Induced acetylcholinesterase-rich layer in rat dentate gyrus following entorhinal lesions

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.

Insulin-like growth factor-1 mRNA is increased in deafferented hippocampus: spatiotemporal correspondence of a trophic event with axon sprouting

Deafferentation is known to induce axonal sprouting in adult brain, but the signals that direct this response are not understood. To evaluate the possible roles of insulin-like growth factor-1 (IGF-1) and basic fibroblast growth factor (bFGF) in central axonal sprouting, the present study used in situ hybridization to evaluate IGF-1 and bFGF mRNA expression in entorhinal deafferented rat hippocampus. Alternate tissue sections were processed for Fink-Heimer impregnation of axonal degeneration, Bandeiraea simplicifolia (BS-1) labeling of microglia, and glial fibrillary acidic protein immunocytochemistry. In control hippocampus, IGF-1 mRNA was localized to a few neurons, with no labeled cells in the dentate gyrus molecular layer; bFGF cRNA hybridization was diffuse in dendritic fields but was dense in CA2 stratum pyramidale. Both mRNA species were increased by deafferentation. The distribution of elevated IGF-1 mRNA corresponded precisely to fields of axonal degeneration and was greatest in the dentate gyrus outer molecular layer and stratum lacunosum moleculare. In these fields, IGF-1 mRNA was elevated by 2 days, reached maximal levels at 4 days, and declined by 10 days postlesion. Double labeling revealed that the majority of IGF-1 cRNA-labeled cells were microglia. In deafferented hippocampus, bFGF mRNA was broadly increased across fields both containing and lacking axonal degeneration. In the dentate, bFGF mRNA levels peaked at 5 days postlesion and remained elevated through 14 days. These results demonstrate that reactive microglia within deafferented hippocampal laminae express IGF-1 mRNA just prior to and during the period of reactive axonal growth and suggest that IGF-1 plays a role in directing the sprouting of spared afferents into these fields.

Enhanced but delayed axonal sprouting of the commissural/associational pathway following a combined entorhinal cortex/fimbria fornix lesion

From previous lesion studies of the hippocampus it has been reported that axons of the commissural/associational pathway expand their termination zone in the molecular layer of the dentate gyrus by 20-25% in response to loss of input from the entorhinal cortex. However, although much is known about the response of the commissural/associational pathway with regard to extent, latency, and speed of the reinnervation response following an entorhinal cortex lesion, little is known about how the loss of additional afferent systems might modulate this response. To address this issue, we examined at 14, 30, and 45 days postlesion, the sprouting of commissural/associational afferents following either a unilateral fimbria fornix transection, a unilateral entorhinal cortex lesion, or combined lesions of both the entorhinal cortex and the fimbria fornix. Loss of septal innervation to the hippocampus was assessed using the cholinesterase stain, whereas sprouting from the commissural/associational pathway was determined from Holmes fiber-stained sections. In addition, the Timms stain was used to examine the time course of the loss of terminal fields of the various zinc-containing afferent systems within the hippocampus. Following the removal of input to the hippocampus via the fimbria fornix transection, there was no evidence of sprouting of the commissural/associational fibers into the deafferented portion of the dentate gyrus. In contrast, rats receiving an entorhinal cortex lesion showed a significant increase (28%) in the width of the commissural/associational fiber plexus that was present by 14 days postlesion. By comparison, the magnitude of the expansion of the commissural/associational fiber plexus was significantly larger after lesioning both the entorhinal cortex and the fimbria than after the entorhinal cortex lesion alone (45% vs. 28%). In addition, the expansion of the commissural/associational fiber plexus was not increased at 14 days postlesion but was significantly increased at 30 days postlesion. The delay in the sprouting of the commissural/associational pathway coincided with the time course of loss of zinc-containing fibers in the outer molecular layer of the dentate gyrus as assessed with the Timms stain. These results suggest that the magnitude and time course for the sprouting of axons from the commissural/associational pathway into the partially deafferented hippocampus of the adult rat is lesion dependent and that the effect of the loss of input from the entorhinal cortex can be modulated and enhanced by the concomitant depletion of input from the fimbria fornix.

Glutamate dehydrogenase in astrocytes of the rat dentate gyrus following lesion of the entorhinal cortex

Applying quantitative microscopic histochemistry, the activity of the mitochondrial glutamate dehydrogenase which is localized in astrocytes was determined in the molecular layer of the dentate gyrus of the rat hippocampus. This hippocampal region contains the important terminations of the glutamatergic perforant path. For comparison, determinations of the mitochondrial succinate dehydrogenase were performed, which is localized preferentially in terminals and dendrites. Two age groups of animals were examined: young adults (three months old) and aged subjects (24 months old). Both age groups were divided into controls, and animals killed three, 21 and 90 days following unilateral electrolytic lesion of the entorhinal cortex. The post-lesional shrinkage of the terminal field of the perforant path, ipsilateral to the lesion side, was determined and considered in the evaluation of enzymatic data. Statistic analysis revealed that ipsilateral to the lesion side there was a significant decrease of glutamate and succinate dehydrogenase activities in the terminal field of the perforant path three, 21 and 90 days following lesion. It is reasonable to assume that the decrease of succinate dehydrogenase activity (50-60%) was caused by the loss of mitochondria localized in degenerating terminals, whereas the decrease of glutamate dehydrogenase activity (20-30%) was related to the decrease of glutamatergic transmission following lesion. In the terminal field of the perforant path contralateral to the lesion side both significant increases and decreases of enzyme activities were measured following lesion. From these results it is concluded that the hippocampus contralateral to the lesion side cannot be considered as an appropriate intraindividual control. The comparison between young and aged animals showed no differences in the demonstration of glutamate dehydrogenase and only restricted differences in the activity level of succinate dehydrogenase post-lesion. Therefore, it is reasonable to assume that the post-lesional reactivity of the enzymes studied was very similar in both age groups.

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.

Deafferentation removes calretinin immunopositive terminals, but does not induce degeneration of calbindin D-28k and parvalbumin expressing neurons in the hippocampus of adult rats

Unilateral combined transections of the fimbriafornix and angular bundle in adult Fischer 344 rats were used to study the effects of deafferentation on hippocampal expression of calretinin, calbindin D-28k, and parvalbumin. Reflecting the widespread degeneration of synaptic contacts, immunostaining for glial fibrillary acidic protein 6 days after the lesions was increased in lacunosum-molecular and oriens layers of CA1, 2, and 3 in ipsi- and contralateral hippocampus and in the ipsilateral dentate gyrus outer molecular layer. At 21 days the immunoreactivity had decreased to control levels except for a still slightly increased signal in the oriens layer of CA1-3. At 6 and 21 days after the combined lesions the numbers of hippocampal neurons containing calretinin, parvalbumin, and calbindin D-28k was unaltered. The combined lesions abolished calretinin containing terminals in the dentate gyrus inner molecular layer on the deafferentated side. This could be reproduced by single unilateral fimbria-fornix transections, suggesting that the axons of these calretinin positive terminals project to the hippocampus through the fimbria-fornix. The most likely origin of the calretinin positive terminals are neurons in the supramammillary hypothalamic nucleus. Our findings demonstrate that the extensive lesion-induced synaptic rearrangements in the adult hippocampus do not induce degeneration of hippocampal neurons expressing calretinin, calbindin D-28k, and parvalbumin, but do remove calretinin containing terminals which reach their targets in the hippocampus through the fimbria-fornix.

Nerve growth factor in CNS repair

The hypothesis that neurotrophic factors play important roles in the adult central nervous system (CNS) has been successfully investigated in the past decade with regard to experimental and pathologic situations. Trophic roles in adult CNS axonal regeneration, on the other hand, have received much less attention. We review three groups of recent studies that demonstrate the relevance of nerve growth factor (NGF) for the regeneration of selected axons into adult central nervous tissue. The first group concerns a septohippocampal model where transected septal cholinergic axons are allowed to regrow into the hippocampal formation through a peripheral nerve bridge implanted into the transection lesion gap. NGF is required in the bridge, enhances penetration of the hippocampal tissue when infused there, and both attracts and promotes sprouting within the septum when infused in the lateral ventricle or the septal tissue itself. The second group of studies concerns the development of a spinal cord sensory regeneration model, where dorsal root ganglionic axons regrow into a nerve bridge placed within the dorsal spinal cord. Preliminary data indicate that NGF infusion rostral to the bridge once again promotes substantial penetration of the adult cord tissue by the regenerating NGF-sensitive fibers. In the third group of studies, attention has been shifted to the location of endogenous NGF in the adult rat hippocampal formation and the normal or lesion-induced occurrence of extrasomal NGF immunoreactivity. These regions of anchored NGF have the ability to attract NGF-sensitive growing axons and may provide opportunities to investigate local cues for final definition of terminal fields.

Morphological and behavioural effects of granule cell degeneration induced by intrahippocampal fluid injections in intact and fimbria-fornix lesioned rats

This study was aimed at determining whether granule cell degeneration induced by intragyral injections of a neutral fluid (0.9% NaCl with 0.6% glucose, pH 7.0, 2 sites per hippocampus, 2 microliters/site, 1 microliter/min) produced behavioural deficits in rats which, 2 weeks prior to the injections had received either fimbria-fornix lesions or sham-operations. In both sham-operated and lesioned rats, we found such injections to induce a comparable, topographically-limited loss of granule cells in the dorsal leaf of the dentate gyrus and, in the close vicinity of the degeneration area, a severe shrinkage of the molecular layer with concomitant morphological reorganizations (e.g. acetylcholinesterase reaction products were distributed uniformly throughout the molecular layers of sham-operated rats). While the fimbria-fornix lesions produced classically reported behavioural deficits (hyperactivity in both a familiar and an unfamiliar environment. reduced T-maze alternation rates and impaired radial-maze performance), we could not detect adversive effects of the granule cell degeneration on either of these variables in sham-operated and lesioned rats. Our data suggest that limited granule cell degeneration induced by intragyral fluid injections has no effect on locomotor activity, spontaneous alternation and spatial learning. Therefore, we may also infer that the granule cell damage observed after an intragyral implantation of a fetal neural cell suspension does probably not account for the behavioural deficits which, in some experiments, have been found in fimbria-fornix lesioned rats bearing intragyral cell suspension grafts.

Changes in nerve growth factor immunoreactivity following entorhinal cortex lesions: possible molecular mechanism regulating cholinergic sprouting

To assess the possible role of trophic factors in lesion-induced plasticity, we have used a sensitive immunohistochemical technique to evaluate changes in nerve growth factor (NGF) staining in the hippocampal formation 3, 8, 16, and 30 days following entorhinal cortex lesions. Our results indicate that a band of NGF immunoreactivity appears in the outer molecular layer of the ipsilateral dentate gyrus following entorhinal ablation. The distribution of the NGF-immunoreactive band exactly coincides with the distribution of sprouting cholinergic terminals revealed by acetylcholinesterase histochemistry or NGF-receptor immunostaining. Increased NGF-immunoreactivity is detectable at 3 days postlesion, is most intense at 8 days, and decreases to near control levels by 30 days. Lesion-induced increases in NGF immunostaining also occur in animals in which septohippocampal fibers had been removed by prior destruction of the fimbria-fornix. Increases in NGF-immunoreactivity, however, are substantially reduced in animals receiving intraventricular injections of colchicine, which presumably blocks NGF release. These results indicate that 1) increases in NGF immunostaining, which occur following entorhinal lesions, precede any changes in cholinergic sprouting parameters and are greatest during the period of maximal cholinergic sprouting; 2) increased NGF-immunoreactivity is not due to NGF binding by septohippocampal fibers; and 3) increased NGF-immunoreactivity appears to depend on the release of NGF by neurons that produce it. We hypothesize that, following entorhinal lesions, NGF immunostaining within the hippocampal formation may represent NGF "anchored" within the tissue and that NGF accumulation by such a mechanism may direct the sprouting response of NGF-sensitive cholinergic neurons.

A subset of calretinin-positive neurons are abnormal in Alzheimer's disease

The distribution of the calcium-binding protein calretinin was investigated by immunohistochemistry in the hippocampus, the subicular areas, and the entorhinal cortex in patients with Alzheimer's disease and in control subjects. By double immunolabelling, the calretinin immunoreactivity was compared to the immunoreactivity for beta/A4 amyloid or for tau proteins. Calretinin-positive neurons were mainly observed in the molecular layer of the gyrus dentatus, the stratum radiatum of the Ammon's horn, and in layers II and III of the entorhinal cortex. The general pattern of calretinin immunoreactivity was conserved in Alzheimer's disease. Calretinin-positive neurons appeared normal in the hippocampus but had a reduced dendritic tree in the entorhinal cortex. Dystrophic calretinin immunoreactive fibres were often observed in the outer molecular layer of the gyrus dentatus and in the CA4 sector in Alzheimer's disease. Most neurons containing neurofibrillary tangles were not calretinin immunoreactive and most senile plaques were not associated with calretinin positive fibres. These results show that entorhinal calretinin-positive neurons are affected in Alzheimer's disease in spite of an absence of systematic association with neurofibrillary tangles and senile plaques.

Traumatic lesions and transplants of granule cells in the dentate gyrus alter the distribution of afferent fibers in the molecular layer

The present experiments determined whether traumatic lesions of the dentate gyrus granule cells had a different effect on the afferents in the molecular layer (ML) than nontraumatic lesions. Nontraumatic lesions of the granule cells induced by colchicine, ibotenic acid, x-radiation, and adrenalectomy have been reported to reduce both the acetylcholinesterase (AChE)-positive fibers and entorhinal afferents in the ML. After the nontraumatic granule cell lesions, the laminar distribution of the entorhinal afferents was maintained in the ML, whereas the AChE laminar pattern was lost. In the present study, dentate granule cells were traumatically lesioned by a fluid injection into the infragranular cleavage plane (IGCP) of the dentate gyrus. The traumatic lesion resulted in an altered distribution of the afferents in the ML. The perforant path fibers, shown by injection of wheat germ agglutinin horseradish peroxidase into the entorhinal cortex, occupied a greater proportion of the ML in lesioned animals than in control animals. The normal laminar pattern of AChE-positive afferents was not present after the granule cell lesion. There was an initial increase in AChE-positive fibers in the ML that lasted several weeks but eventually returned to near normal levels. The altered distribution of afferents could in part be due to uneven shrinkage of the molecular layer and/or sprouting of the afferents. Granule cell suspension transplants into the IGCP also traumatically lesioned the host granule cells but immediately replaced the damaged host granule cells with immature granule cells. The distribution of afferents was similar to that found in lesioned-only animals. The traumatic lesion induced MAP2 immunoreactivity in the anisomorphic reactive astrocytes of the ML. At the longer survival times, MAP2 was not seen in either the astrocytes of the ML or in the isomorphic reactive astrocytes in CA3.

Alterations in GAP-43 and synapsin immunoreactivity provide evidence for synaptic reorganization in adult cat dorsal lateral geniculate nucleus following retinal lesions

Growth-associated protein-43 (GAP-43) and synapsin were used as molecular markers for synaptic reorganization in the adult cat visual system following sensory deprivation. Small binocular retinal lesions (central 10 degrees) were made with a xenon light photocoagulator in adult cats. One, 3, 5 and 7 weeks after induction of the lesion, the neuropil levels of synapsin and GAP-43 in the dorsal lateral geniculate nucleus (dLGN) and area 17 were determined by immunocytochemistry. GAP-43 displayed a moderately low basal level in the dLGN of normal adult cats. The parvocellular C layers and the interlaminar plexi were characterized by higher immunoreactivity for GAP-43. Lesion-induced alterations were observed in all layers: GAP-43 immunoreactivity increased in the part of the dLGN representing central vision. This increase was maximal 3 weeks after the lesion. Under our experimental conditions, sensory deprivation did not significantly alter GAP-43 levels in the visual cortex. The changes in synapsin immunoreactivity were also restricted to the dLGN. In this nucleus, synapsin immunoreactivity decreased in all layers in the part subserving central vision 1 week after lesion. By 3 weeks after lesion, the level of synapsin had already returned to normal. This study provides evidence for a capacity for structural remodelling in primary sensory brain areas such as the dLGN throughout adult life. The observed changes in GAP-43 and synapsin in the dLGN suggest that synaptic reorganization is induced by retinal lesions. Normalization of synaptic density and activity could be important for the survival of the partially deafferented geniculate neurons.

Dynamics of synapsin I gene expression during the establishment and restoration of functional synapses in the rat hippocampus

Synapse development and injury-induced reorganization have been extensively characterized morphologically, yet relatively little is known about the underlying molecular and biochemical events. To examine molecular mechanisms of synaptic development and rearrangement, we looked at the developmental pattern of expression of the neuron-specific gene synapsin I in granule cell neurons of the dentate gyrus and their accompanying mossy fibers during the main period of synaptogenic differentiation in the rat hippocampus. We found a significant difference between the temporal expression of synapsin I messenger RNA in dentate granule somata and the appearance of protein in their mossy fiber terminals during the postnatal development of these neurons. Next, to investigate the regulation of neuron-specific gene expression during the restoration of synaptic contacts in the central nervous system, we examined the expression of the synapsin I gene following lesions of hippocampal circuitry. These studies show marked changes in the pattern and intensity of synapsin I immunoreactivity in the dendritic fields of dentate granule cell neurons following perforant pathway transection. In contrast, changes in synapsin I messenger RNA expression in target neurons, and in those neurons responsible for the reinnervation of this region of the hippocampus, were not found to accompany new synapse formation. On a molecular level, both developmental and lesion data suggest that the expression of the synapsin I gene is tightly regulated in the central nervous system, and that considerable changes in synapsin I protein may occur in neurons without concomitant changes in the levels of its messenger RNA. Finally, our results suggest that the appearance of detectable levels of synapsin I protein in in developing and sprouting synapses coincides with the acquisition of function by those central synapses.

Divergence of hippocampal mossy fibers

By connecting the fascia dentata with the hippocampus proper, the axons of the granule cells, the mossy fibers, represent an important element of the main excitatory, trisynaptic pathway of the hippocampal formation. In this review the various synaptic connections of the mossy fibers are discussed. It turns out that the mossy fibers do not only establish synapses with the pyramidal neurons of regio inferior as traditionally assumed, but a variety of local circuit neurons as well as projection cells are also contacted by the mossy fibers. Thus there is an underestimated divergence of the impulse flow within the "trisynaptic" pathway at the level of the mossy fibers. Similarly, the pattern of afferent input to the granule cells, especially that of GABAergic neurons, is more complex than previously assumed. In this respect the concept of a unidirectional "trisynaptic" pathway certainly is an oversimplification. In particular, the hilus of the fascia dentata, that the mossy fibers traverse on their way to regio inferior, is often neglected in this concept. The hilar region comprises a large variety of morphologically and functionally distinct neuronal types that, to a large extent, are targets of hilar mossy fiber collaterals. By focusing on the mossy fiber system, an attempt is made in this review to summarize new data on hippocampal circuitries that have been accumulated since the original description of the trisynaptic pathway. This concept, which originally comprised the synapses of the perforant path fibers on dentate granule cells, the mossy fiber synapses on CA3 pyramidal neurons, and the synapses of the Schaffer collaterals on CA1 pyramidal cells, has been of great heuristic value but needs to be modified in view of recent morphological and physiological data.

Cholinoceptive cells in rat cerebral cortex: somatodendritic immunoreactivity for muscarinic receptor and cytoskeletal proteins

Adult rat telecephalon was surveyed for cells demonstrating immunopositivity for muscarinic receptor (M35 antibody), microtubule-associated proteins, neurofilaments, and brain-spectrin. Neurons immunostained for muscarinic receptor were found in frontal, parietal, temporal, and occipital isocortex where they accounted for approximately 15-16% of all neurons. This labeling involved a large proportion of layer V pyramidal cells, some layer III pyramidal cells and a small proportion of non-pyramidal cells in layers II-VI. In the hippocampus, pyramidal cells, non-pyramidal cells and granular cells were immunoreactive, as were many pyramidal cells in subicular and entorhinal cortices. In every cortical region examined, cells demonstrating muscarinic receptor were morphologically identical to cells stained lightly to moderately for acetylcholinesterase following pretreatment with diisopropylfluorophosphate, and they were found in similar numbers and in a similar laminar distribution. These characteristics further corresponded to those of cells whose somatodendritic compartments were intensely immunostained by antibodies to microtubule-associated proteins (MAP): MAP-1, MAP-2, MAP-5; neurofilament proteins (NF): NF-68kD, NF-160kD, NF-200kD; and brain-spectrin. Double immunostaining using a fluorescence method followed by an avidin-biotin staining procedure revealed that cortical cells which possessed immunoreactivity for muscarinic receptor demonstrated an 80-85% overlap with cells that were immunoreactive for MAP-2 (and tau) or NF-200kD. Following unilateral ibotenic acid lesions of the nucleus basalis, MAP-2 immunostaining was reduced in the ipsilateral isocortex. This significant reduction was most evident in the parietal cortex, exactly where maximal loss of acetylcholinesterase-containing fibers occurred. The same lesion produced no significant difference in immunodensity of muscarinic receptor, MAP-1, MAP-5 NF-68kD, NF-160kD and NF-200kD. Thus, cortical cholinoceptive cells are enriched with cytoskeletal components and cholinergic afferents modulate cortical MAP-2.

Entorhinal cortex lesions transiently alter glucocorticoid but not mineralocorticoid receptor gene expression in the rat hippocampus

Entorhinal cortex lesions destroy an important hippocampal input and lead to axonal sprouting in the dentate gyrus. Glucocorticoids are known to inhibit this reinnervation process. In the present study, we examined changes in hippocampal glucocorticoid receptor (GR) and mineralocorticoid receptor (MR) mRNA expression using in situ hybridization following unilateral entorhinal cortex lesioning (ECL) in the rat. As early as 1 day postlesioning, a 33% bilateral decrease in GR mRNA expression was observed in the dentate gyrus. By contrast, a 36% bilateral increase in GR mRNA expression was detected in the CA1 cell field. GR mRNA levels in both regions returned to those of control animals 2 days postlesioning, indicating that these effects were transient. Adjacent sections hybridized with probes to MR mRNA revealed no changes in hippocampal MR gene expression as a result of ECL. The selective decrease in GR mRNA expression observed in the dentate gyrus following ECL is specific to the hippocampal subregion targeted for reactive synaptogenesis and thus may serve to attenuate the inhibitory actions of circulating glucocorticoids.

Cholesterol synthesis and lipoprotein reuptake during synaptic remodelling in hippocampus in adult rats

Apolipoprotein E is synthesized and secreted by astrocytes in the hippocampus following lesions of the entorhinal cortex. It was proposed that apolipoprotein E, by analogy to its role in cholesterol transport in circulation, could be involved in the salvage and reutilization of non-esterified cholesterol released during terminal breakdown. The salvaged cholesterol could then be transported to neurons by apolipoprotein E-complexes and taken up via the apolipoprotein E/apolipoprotein B (low-density lipoprotein) receptor. To test this hypothesis, we have examined low-density lipoprotein receptor binding in brain sections of rats undergoing hippocampal reinnervation. The number of neuronal cells labelled by fluorescent Dil-low-density lipoprotein as well as the density of [125I]low-density lipoprotein binding sites in the dentate gyrus were found to increase in parallel with the extent of cholinergic reinnervation occurring in the deafferented hippocampus. In contrast, hippocampal cholesterol synthesis fell by more than 60% at eight days post-lesion, but eventually returned to control levels at 30 days post-lesion. The transient loss of cholesterol synthesis coincided with a peak in hippocampal apolipoprotein E expression. A concomitant accumulation of sudanophilic lipids (cholesterol esters and phospholipids) was detected in the outer molecular layer of the dentate gyrus and in the hilar region. The present findings suggest that non-esterified cholesterol released during terminal breakdown is esterified, transported via the apolipoprotein E transport system to neurons undergoing reinnervation, and take-up through the low-density lipoprotein receptor pathway where it is presumably used as a precursor molecule for the synthesis of new synapses and terminals.

Acetylcholinesterase activity and post-lesional plasticity in the hippocampus of young and aged rats

Applying quantitative microscopic histochemistry, the activity of acetylcholinesterase was determined in the various layers of the rat hippocampus at three different levels along the rostrocaudal extent. Two age groups of animals were examined: young adults (two to three months old) and aged subjects (26 months old). Young adults were divided into controls, and animals killed eight and 35 days following bilateral ibotenate lesioning of the medial septum-diagonal band complex. Aged rats were divided into controls and animals 35 days post-lesion. Analysis of variance revealed that the mean acetylcholinesterase activities of the entire hippocampus of individuals were not significantly different between young and aged rats when averaged across controls and 35 days post-lesion. There was a significant decrease of acetylcholinesterase activity (-52%) in young adults eight days post-lesion as compared to controls, but a significant increase (+63%) took place until 35 days post-lesion as compared to eight days post-lesion. Significantly lower activities existed, however, in young (-22%) and aged rats (-18%) 35 days post-lesion as compared to controls. This decrease in mean activity was not age dependent. As acetylcholinesterase is considered to be a good cholinergic indicator in the hippocampus, the results suggest a homotypic collateral sprouting from spared cholinergic afferents following ibotenate lesion of the medial septum-diagonal band complex in young and aged rats. Based on the data obtained, it is reasonable to assume that there was no difference in the post-lesional plasticity of neuronal acetylcholinesterase between young adult and aged rats.

Entorhinal cortex lesion induces differential responses in [125I]insulin-like growth factor I, [125I]insulin-like growth factor II and [125I]insulin receptor binding sites in the rat hippocampal formation

The hippocampus can be induced by deafferentation to selectively reorganize its neuronal input. Entorhinal cortex lesion, which causes degeneration of the perforant pathway, evokes sprouting of septal afferents as well as glutamatergic commissural/associational fibers in the deafferentated zone of the molecular layer of the dentate gyrus. Although the process of reactive synaptogenesis that follows deafferentation has been extensively studied, at present little is known about its molecular basis and the mechanism of initiation. In this study, following unilateral lesion of the entorhinal cortex, the time-course of possible alterations of insulin-like growth factors I and II, and insulin binding sites were evaluated by in vitro quantitative receptor autoradiography. [125I]Insulin-like growth factor I receptor binding sites did not exhibit any significant variation between the contralateral and ipsilateral hippocampal formation at any time periods following lesion except in the molecular layer of the dentate gyrus (P < 0.05) at day 8. However, when compared with the unlesioned animals, a differential time-dependent response of [125I]insulin-like growth factor I binding sites was noted in selective layers of the hippocampus. [125I]Insulin-like growth factor II receptor binding sites showed a significant decrease (P < 0.05) in the ipsilateral granular cell layer of the dentate gyrus only at day 14 post lesion. Interestingly, compared to controls, a dramatic bilateral increase (P < 0.05) in [125I]insulin-like growth factor II binding was evident between days 1 and 8 in most layers of the hippocampal formation. A lesion-induced bilateral increase (P < 0.05) in [125I]insulin binding sites was evident in all layers of the hippocampus between two to eight days and at 30 days post lesion. In selective layers, however, a significant increase (P < 0.05) in [125I]insulin binding sites was also observed at days 1 and 14 after lesion. These results, which are compatible with the process of degeneration and/or sprouting of the terminal fibers, suggest possible involvement of insulin-like growth factors and insulin in the sequence of molecular events that occur to facilitate neuronal repair and to promote neuronal survival following entorhinal cortex lesion.

Increased sensitivity to adenosine in the rat dentate gyrus molecular layer two weeks after partial entorhinal lesions

The molecular layer of the dentate gyrus exhibits extensive circuit and receptor reorganization after entorhinal lesions and in Alzheimer's disease, including decreased adenosine (A1) receptor binding in the terminal zone of damaged perforant path fibers. We examined the adenosine-sensitivity of evoked synaptic activity recorded from the rat dentate gyrus molecular layer in hippocampal slices prepared after electrolytic lesions were placed in approximately the middle third of the entorhinal cortex. Extracellular field potentials (EFPs) recorded in slices prepared from animals two days post-lesion were small, upward-going, and exhibited paired-pulse potentiation, but by two weeks post-lesion EFPs had recovered to large, downward-going responses that exhibited paired-pulsed depression. EFPs recorded from two week post-lesion slices were about 2-fold more sensitive (P < or = 0.05) to exposure to adenosine when compared to EFPs recorded from slices from unlesioned animals. Adenosine-induced reduction of paired-pulse depression was similar between unlesioned and post-lesion slices. AChE histochemistry performed after recording revealed dense staining in the dentate gyrus molecular layer of post-lesion slices as compared to slices from unlesioned animals, confirming that sprouting of cholinergic fibers occurred as expected from previous entorhinal lesion studies. Autoradiography performed on adjacent slices showed a decrease in binding to A1-adenosine receptors in the dentate gyrus molecular layer in post-lesion slices as compared to slices from unlesioned animals, indicating that there was a loss of presynaptically located A1-adenosine receptors on damaged perforant pathway terminals. These results indicate that, in addition to the recovery of the major excitatory signal to the hippocampus after entorhinal cell loss, this signal is more sensitive to modulation by adenosine, suggesting an increase in A1-adenosine receptor efficacy in the reinnervated region.

[3H]phorbol ester binding sites and neuronal plasticity in the hippocampus following entorhinal cortex lesions

Entorhinal cortex lesioning (ECL) produces a loss of more than 80% of the synapses in the outer molecular layer of the hippocampus. However, the loss of synapses is transient. Beginning a few days after denervation, new synapses are formed, virtually replacing the lost inputs within 2 months. Synaptic remodelling induced by ECL is associated with specific modifications of neurotransmitters, hormones and growth factors. Particularly, protein kinase C (PKC) plays important functional roles in receptor-mediated transmembrane signal transduction. PKC is also involved in various aspects of synaptic plasticity, such as cellular growth and differentiation. To investigate further the potential roles of PKC in synaptic plasticity observed in the ECL model, [3H]phorbol 12,13-dibutyrate ([3H]PDBu) binding, a putative marker of PKC, was examined at different times post-lesion. [3H]PDBu binding sites transiently decreased bilaterally at 2 and 8 days post-lesion (20%) in different laminae and sub-fields of the rostral hippocampus but returned to control values at 14 and 30 days post-lesion. In caudal portion of the hippocampus, [3H]PDBu binding was also decreased at 2 days post-lesion but only on the contralateral side. Interestingly, [3H]PDBu binding sites in the cortex increased by up to 30% in the contralateral side while no significant change was observed in the ipsilateral side at any time post-lesion. It is known that PKC can be regulated by different systems following alterations of neuronal and glial activity. We suggest that these could be involved in the response of PKC and [3H]PDBu binding sites following ECL. Moreover, PKC seemed to be modified in different brain areas in neuronal inputs from the entorhinal cortex and the subsequent reinnervation process.

Injections of fluid or septal cell suspension grafts into the dentate gyrus of rats induce granule cell degeneration

This study was originally aimed at investigating the effects of intragyral cell suspension grafts which had been enriched in basic fibroblast growth factor (bFGF) before being implanted into the rat hippocampus denervated by aspiration of the septohippocampal pathways. Whether treated with vehicle alone, vehicle + bFGF, cell suspension with or without bFGF, and irrespective of the surgical treatment (sham-operation, lesions or lesions + grafts), we unexpectedly found approximately 80% of the rats to show morphological alterations in the dentate gyrus (20 weeks post-grafting). These alterations consisted of loss of a part of the granule cells; this loss was most often located in the dorsal leaf of the dentate gyrus. Also, in the close vicinity of the degeneration area, we found severe shrinkage of the molecular layer and disappearance of the typical laminae pattern of acetylcholinesterase distribution. These observations confirm previous findings which showed that fluid injections into the dentate gyrus, a widely used technique for intracerebral administration of drugs, trophic factors or neural grafts, may induce undesirable granule cell necrosis.

Signals that induce sprouting in the central nervous system: sprouting is delayed in a strain of mouse exhibiting delayed axonal degeneration

This study evaluates whether CNS sprouting is initiated by signals related to the degeneration of presynaptic axons. We evaluate the time course of sprouting of cholinergic septohippocampal fibers after unilateral entorhinal cortex (EC) lesions in a substrain of mice carrying a mutation which leads to a substantial delay in the onset of Wallerian degeneration. We first verified that axonal degeneration resulting from EC lesions was delayed in mutant mice using silver-staining techniques (the Fink-Heimer method). Cholinergic sprouting was then evaluated using a histochemical technique for acetylcholinesterase (AChE) in mutant mice and normal controls. In normal control mice, both axonal degeneration and cholinergic sprouting occurred with a time course that was comparable to that described in rats. Argyrophilic degeneration debris was prominent by 4 days postlesion, and increases in AChE staining in the molecular layer of the dentate gyrus were well developed by 10 days. In mice carrying the "Ola" mutation, however, argyrophilic degeneration debris was not detectable at 4 or 6 days postlesion, began to appear in the dentate gyrus by 8 days postlesion, but did not become prominent until 12 days. Increases in AChE staining in the molecular layer of the dentate gyrus were not detectable even at 12 days postlesion, but developed gradually after 14 days. These results demonstrate that the signals which initiate at least one form of CNS sprouting are related to the degeneration of presynaptic axons.

Modulation of gamma-actin and alpha 1-tubulin expression by corticosterone during neuronal plasticity in the hippocampus

Evidence is given for altered gene expression of gamma-actin in the hippocampus in response to entorhinal cortex lesion (ECL). Time course analysis reveals a progressive repression of gamma-actin expression between 4 and 14 days post-lesion, coinciding with the early and middle phases of the hippocampal reinnervation process. RNA prevalence returns to near control values at 30 days post-lesion. Corticosterone administration, which is known to impair the reinnervation process in ECL rats, prevents the lesion-induced reduction in gamma-actin expression and blocks the induction of alpha 1-tubulin in the deafferented hippocampus. The timing of response of gamma-actin to ECL and its modulation by glucocorticoid administration support suggestions that gamma-actin has an important role to play in neuronal cytoarchitecture remodelling during hippocampal reinnervation.

Specificity of interneuronal connections

A fundamental problem of neurobiological research is how specific connections between individual neurons are established and maintained. In this report different levels of neuronal specificity are described. Some neuronal populations display region specificity, but within the target region they establish synapses with a variety of neurons. A characteristic feature of the afferent innervation of hippocampal neurons is that many fibers terminate in a laminated fashion. Such a layer specificity is known for the afferents from the entorhinal cortex and for the mossy fibers. The entorhinal afferents terminate in the outer molecular layer of the fascia dentata and in the stratum lacunosum-moleculare of the hippocampus proper. The mossy fibers display both region specificity and layer specificity: they form numerous synapses in hippocampal region CA3 but never invade CA1; in CA3 they are restricted to stratum lucidum. An extremely high degree of neuronal specificity is observed in the case of the axo-axonic or chandelier cells. The axons of these neurons specifically terminate on the axon initial segments of projection neurons in the neocortex, hippocampus and fascia dentata. Thus, these cells not only display a target cell specificity but a selectivity for a distinct portion of the target cell's membrane. Some of the factors that contribute to these different levels of neuronal specificity are briefly discussed. Positional cues as well as diffusible molecules from the target region may guide the outgrowing growth cone to its target. Molecular interactions between pre- and postsynaptic membranes, the functional load of the synaptic contact, and the selective death of a number of neurons and synapses further determine the specificity of interneuronal connections.(ABSTRACT TRUNCATED AT 250 WORDS)

bFGF promotes the survival of entorhinal layer II neurons after perforant path axotomy

Infusion of basic fibroblast growth factor (bFGF) prevents the loss of cholinergic neurons in the septum/diagonal band of broca following fimbria-fornix transection. However, an in vivo test of whether bFGF will also rescue injured non-cholinergic or cortical neurons has not been carried out. Previous studies have shown that the majority of layer II stellate neurons utilize an excitatory amino acid as their neurotransmitter. In order to determine if bFGF acts on non-cholinergic cortical neurons, a paradigm was developed to examine whether or not bFGF could spare layer II entorhinal stellate cells from axotomy induced death or atrophy. Axotomy of the medial entorhinal cortex fibers projecting to the dentate gyrus of the hippocampal formation via the perforant path lead to retrograde cell loss in entorhinal cortex. Fourteen or thirty days after a unilateral knife cut axotomy of the perforant path, layer II of medical entorhinal cortex showed a 28% decrease in large stellate neurons as well as many weakly stained, hollow cells compared to the non-lesioned side or naive controls. Layer IV neurons, however, which do not project via the perforant path, showed little detectable change in the number of cells ipsilateral to the knife-cut as compared to the contralateral side. Intraventricular infusion of bFGF over a period of 14 days reduced the 28% cell loss to less than 6%. Thus, bFGF is capable of preventing cortical neuronal loss and/or atrophy associated with retrograde degeneration of non-cholinergic neurons following axotomy.

New mRNA probes for hippocampal responses to entorhinal cortex lesions in the adult male rat: a preliminary report

Three new mRNA responses were found in the hippocampus of the adult male rat after entorhinal cortex lesions (ECL) that induce synaptic reorganization. Hippocampus cDNA libraries were screened by a subtractive hybridization strategy designed to detect ECL-induced mRNAs. Partial sequencing showed clones with similarities to mouse vimentin, ferritin, and polypeptide 7B-2. A sequence similar to mouse SNAP-25 sequence was also detected. Using a mouse SNAP-25 probe, rat SNAP-25 mRNA increased in the hippocampus after ECL.

Dendritic localization of type II calcium calmodulin-dependent protein kinase mRNA in normal and reinnervated rat hippocampus

In situ hybridization histochemistry has revealed a diffuse distribution of the alpha subunit of type II calcium calmodulin-dependent protein kinase (CaM II kinase alpha) mRNA in the neuropil of regions containing CaM II kinase alpha-expressing cells and has led some to propose that it may be expressed in dendrites. In order to determine if CaM II kinase alpha mRNA is expressed in dendrites and if the gene encoding CaM II kinase alpha is regulated in response to synaptic reinnervation, we examined its expression in the hippocampus of normal rats, of rats that had received a unilateral injection of kainic acid and of rats with a unilateral entorhinal cortex lesion. The relatively specific elimination of the CA3 pyramidal cells by kainate lesions precisely correlated with the loss of CaM II kinase alpha cRNA hybridization in the stratum radiatum as well as the stratum pyramidale. Following entorhinal cortex lesions, during the period of new synapse formation in the dentate gyrus, there was no detectable change in the level of CaM II kinase alpha gene expression. These data suggest that CaM II kinase alpha mRNA is expressed in the dendrites of hippocampal pyramidal cells and, therefore, is likely to be expressed in dendrites in other regions of the central nervous system exhibiting CaM II kinase alpha cRNA labeling in the neuropil. However, changes in expression were not found to accompany new synapse formation.

Organization and plasticity of GABA neurons and receptors in monkey visual cortex

The GABA neurons of monkey area 17 are a morphologically and chemically heterogeneous population of interneurons that are normally distributed most densely within the geniculocortical recipient zones of the visual cortex. In adult monkeys deprived of visual input from one eye, the levels of immunoreactivity for GABA and GAD within neurons of these geniculocortical zones is reduced. Similar changes are seen in the levels of proteins that make up the GABAA receptor sub-type. The effects of monocular deprivation on other substances suggest that specific types of GABA neurons, such as those in which the tachykinin neuropeptide family and parvalbumin coexist with GABA, are greatly influenced by changes in visual input. That some proteins remain normal within deprived-eye neurons and that other proteins are increased indicates the changes in the GABA cells of the cortex are not the result of a general reduction in protein synthesis. Comparisons of what is known about the morphological and synaptic features of GABA cells in area 17 and the characteristics of cells affected by monocular deprivation suggests that certain classes, such as the clutch cell, may be preferential targets of deprivation. Such a selective loss of certain GABA neurons would have broad implications for the possible physiological plasticity of cortical cells, for if ongoing studies determine that specific receptive field properties are affected by monocular deprivation in adults, the correlation of functional properties and classes of GABA cells would be possible.

Excitotoxic lesions of the rat entorhinal cortex. Effects of selective neuronal damage on acquisition and retention of a non-spatial reference memory task

The neurotoxin N-methyl-D-aspartate was used to induce selective bilateral neuronal loss in the entorhinal cortex, in order to model one aspect of the neurodegeneration observed in Alzheimer's disease, Down's syndrome and aging. Lesioned, sham-lesioned and intact control rats learned a reference memory task involving a brightness discrimination for water reward. Rats were trained over 1 week until reaching criteria and tested for retention after a 10-day interval. Lesioned rats showed impaired retention compared to shams and controls, but were able to reacquire the task. Anatomical analysis confirmed excitotoxic lesions of the entorhinal cortex, and showed collateral sprouting of acetylcholinesterase-stained fibers into the outer molecular layer of the dentate gyrus, indicating denervation plasticity in the hippocampus. This functional anatomical study of the entorhinal cortex demonstrates the importance of the entorhinal cortex in memory retention, and raises the possibility that functional deficits in certain neurodegenerative diseases may be modeled by partial neuronal loss in the entorhinal cortex.

Lesion of the rat entorhinal cortex leads to a rapid microglial reaction in the dentate gyrus. A light and electron microscopical study

Stereotaxic lesioning of the entorhinal cortex leads to an anterograde axonal degeneration in the molecular layer of the dentate gyrus. As revealed by immunocytochemical and histochemical methods, lesion of the entorhinal cortex induced a proliferation of microglia and an increased expression of established microglial activation markers within the deafferented zone. Reactive microglial cells were detected as early as 24 h after the lesion. The microglial reaction showed a maximum around day 3 post-lesion and disappeared by day 8 post-lesion. Reactive microglia were strongly positive for the B4-isolectin from Griffonia simplicifolia (GSI-B4), expressed high levels of CR3 complement receptor and 5'-nucleotidase, but lacked CD4 and MHC class I and II antigens. In addition, microglial cells were identified using MUC 102, a new monoclonal antibody against rat microglia. At the ultrastructural level, reactive microglial cells were consistently seen to phagocytose degenerating terminals. Our data suggest that (1) axonal degeneration represents a sufficient stimulus for inducing microglial activation and proliferation in the deafferented dentate gyrus; (2) these activated microglial cells are characterized by immunophenotypes different from those observed in other types of CNS injury; (3) the early microglial reaction precedes the well-documented astrocyte reaction in the dentate gyrus; and (4) the timed interaction of microglia and astrocytes could be important for regulating regenerative sprouting processes in the mature CNS.

Sulfated glycoprotein-2 is increased in rat hippocampus following entorhinal cortex lesioning

Thios study showed responses of sulfated glycoprotein-2 (SGP-2) in the rat hippocampus after deafferenting lesion. SGP-2 is a plasma protein that also occurs in many peripheral tissues. In some circumstances, elevations of SGP-2 mRNA are associated with cell degeneration and responses to injury. This study used entorhinal cortex lesions (ECL) to partially deafferent the hippocampus by damaging the perforant path and to induce synaptic remodeling. SGP-2 mRNA is increased in hippocampal astrocytes after ECL. Western blot analysis of soluble hippocampal proteins identified 3 major forms of rat SGP-2 protein: a precursor (61 kDa) and 2 reduced subunits at 39.5 and 35 kDa. These forms increased at 4 days post ECL ipsilaterally to the lesion. By immunocytochemistry (ICC), SGP-2 showed an increased immunoreactivity on the lesioned side by 2 days post ECL that continued through 14 days post ECL. Besides immunopositive astrocytes, punctate immunochemical reaction products occurred among the degenerating fibers of the perforant path. We conclude that changes of SGP-2 protein in the hippocampus after ECL occur roughly in parallel with increases of SGP-2 mRNA. The punctate immuno-deposits could represent secreted SGP-2 and may be useful as a marker for degenerating pathways.

Effects of fimbria-fornix and angular bundle transection on expression of the p75NGFR mRNA by cells in the medial septum and diagonal band of Broca: correlations with cell survival, synaptic reorganization and sprouting

Quantitative in situ hybridization techniques were used to examine the effects of lesions which sever hippocampal cholinergic and cortical afferents on p75NGFR mRNA-expressing cells located in the medial septum (MS) and the vertical (VDB) and horizontal (HDB) limbs of the diagonal band of Broca. Animals received either bilateral transection of the fimbria/fornix, unilateral transection of the angular bundle, or sham surgery. Four days later, animals were sacrificed and sections through the MS, VDB and HDB were processed for detection of the p75NGFR mRNA using in situ hybridization techniques previously described (Mol. Brain Res., 6 (1989) 275-287). Transection of the fimbria/fornix and angular bundle differentially affected p75NGFR-expressing cells in the MS, VDB and HDB within 4 days after injury, in ways which were consistent and correlate with subsequent effects on cell survival, synaptic reorganization and growth. In particular, in the MS and VDB, transection of the fimbria/fornix resulted in a significant decrease in the size of p75NGFR-expressing cells (reductions of 25.9% and 15.1% respectively) which was accompanied by a significant reduction (37.9% and 12.7% fewer grains/cell) in relative levels of p75NGFR mRNA. In contrast, in the HDB, transection of the fimbria/fornix had no significant effect on the average size of p75NGFR-expressing cells; however, a significant increase (49%) in the mean relative level of p75NGFR mRNA was observed which may, in turn, reflect a large increase (as much as 2-3 fold) in the levels of p75NGFR mRNA expressed by a subpopulation of hippocampally projecting cholinergic neurons located in the HDB. Finally, transection of the angular bundle resulted in small, but significant increases (9.4% and 10.9%) in relative levels of p75NGFR mRNA in the MS and VDB, as well as an increase (19.6%) in the number of p75NGFR mRNA-expressing cells in the HDB, on the injured side. No increases in p75NGFR expression in the MS, VDB or HDB contralateral to the lesion were observed; however, a decrease in the size (6.9%) and message content (19.4%) of p75NGFR-expressing cells was detected in the MS contralateral to the lesion. Most importantly, all of these effects are consistent with the subsequent effects of these lesions on the survival of basal forebrain cholinergic cells, and the reorganization and growth of cholinergic afferents to the hippocampal formation.(ABSTRACT TRUNCATED AT 400 WORDS)

Astrocytic apolipoprotein E mRNA and GFAP mRNA in hippocampus after entorhinal cortex lesioning

Entorhinal cortex lesions (ECL) that damage the perforant path to the hippocampus induce rapid increases of apolipoprotein E (apo E) mRNA in the hippocampus. Apo E mRNA was localized in astrocytes by in situ hybridization in combination with immunocytochemistry for glial fibrillary acidic protein (GFAP). Unilateral ECL also increased hippocampal GFAP mRNA, with increases preceding those of apo E mRNA. The apo E mRNA and GFAP mRNA responses were transiently bilateral in non-denervated zones. The timing of response in apo E mRNA to deafferentation supports suggestions that apo E has roles in membrane remodelling during responses to neuron injury.

Reactive synaptogenesis assessed by synaptophysin immunoreactivity is associated with GAP-43 in the dentate gyrus of the adult rat

Reactive synaptogenesis and terminal proliferation are known to occur in the dentate gyrus of the rat hippocampus following removal of specific afferents. In the present study we have examined the relation of synaptophysin immunoreactivity to the immunohistochemical staining pattern of GAP-43, a putative marker of neuritic growth. Within the molecular layer of the normal dentate gyrus, synaptophysin immunolabeling shows a trilaminar pattern, with the inner and outer layers having the greatest density of staining. Within the first week following denervation, there was a significant decrease in the staining density in the outer two-thirds of the molecular layer, followed by a moderate recovery at 14 days and 80% recovery by 30 days. This pattern is consistent with the time course of denervation and reinnervation in this system as determined previously by electron microscopy. By comparison, the staining pattern for GAP-43 in the intact dentate gyrus showed the middle and outer thirds of the molecular layer to be less densely stained than the inner third. Within a week following deafferentation, the outer two-thirds of the molecular layer displayed decreased levels of GAP-43 immunoreactivity, followed by recovery to normal levels by 30 days. By 84 days postlesion, patterns of both synaptophysin and GAP-43 immunostaining reflected an increased width of the inner molecular layer. Laser confocal imaging of double-immunolabeled sections at 14 days postlesion showed a 370% increase in the number of GAP-43-positive terminals in the molecular layer as compared to unoperated controls. Many of these GAP 43-positive terminals were synaptophysin negative. We conclude that GAP-43 may play a role in the synaptic remodeling that occurs in the denervated rat hippocampus and that quantitative morphometry of synaptophysin immunolabeling accurately reflects the fate of presynaptic terminals in this model of degeneration and reinnervation.

Corticosterone differentially regulates the bilateral response of astrocyte mRNAs in the hippocampus to entorhinal cortex lesions in male rats

This study examined the effect of adrenalectomy (ADX) and corticosterone (CORT) replacement on the levels of two astrocyte mRNAs during responses to unilateral entorhinal cortex lesions (ECL) to identify molecular mechanisms involved in glucocorticoid modulation of astrocyte activation following deafferentation. Both glial fibrillary acidic protein (GFAP) and sulfated glycoprotein-2 (SGP-2) mRNA were increased in the ipsilateral hippocampus 4 days following unilateral ECL. In unlesioned ADX rats CORT replacement decreased both messages in the hippocampus. CORT replacement suppressed the ECL-induced increase of GFAP mRNA in the contralateral, but not ipsilateral hippocampus of ADX rats. In contrast, CORT decreased SGP-2 mRNA both ipsi- and contralaterally. It is clear that several regulatory mechanisms are responsible for maintaining a physiological balance of astrocyte activity in the adult brain, and that changes in circuit integrity and the endocrine milieu can alter this balance.

Reinnervation of cerebellar Purkinje cells by climbing fibres surviving a subtotal lesion of the inferior olive in the adult rat. I. Development of new collateral branches and terminal plexuses

Cerebellar climbing fibres react by collateral sprouting after subtotal lesions of the inferior olive, and the newly formed branches are able to reinnervate neighbouring denervated Purkinje cells. In the present paper, we used the Phaseolus vulgaris leucoagglutinin (PHA-L) tracing technique to label the climbing fibres and study their plasticity in detail at the light microscopical level. The specific objectives were to study the time course and morphological aspects of their sprouting, to estimate their extent of growth, and to compare the newly formed terminal plexuses with normal climbing fibres. Intraperitoneal injection of 3-acetylpyridine induced degeneration of the majority of the olivary neurones, which terminate as climbing fibres in the cerebellar cortex. Regularly, small numbers of neurones survived in the inferior olive. In the cerebellar cortex scattered surviving climbing fibres were found, which were devoid of any sign of injury. Already 3 days after the lesion, surviving climbing fibres had emitted collateral branches, which elongated for some distance through the molecular layer and ended with a number of varicosities and very fine branchlets. By 7 days, it was possible to recognize new developing arbours which grew in the molecular layer with the same orientation as normal climbing fibres. At longer survival times, extensive terminal arbours had developed and double labelling experiments confirmed that they terminated around the proximal dendrites of Purkinje cells. The newly formed terminal plexuses resembled, in all essential aspects, normal climbing fibres. In addition, from 1 month onward, it was evident that every surviving climbing fibre was able to form several new terminal plexuses reinnervating a number of neighbouring Purkinje cells. The result of this process was the formation of large clusters of newly formed plexuses around the parental arborization. Quantitative estimates indicated that the domain of innervation of single surviving climbing fibres could be increased by more than six times. It is concluded that climbing fibres surviving a subtotal olivary lesion are capable of extensive sprouting, axonal growth, and formation of new terminal plexuses, which resemble normal climbing fibres. Previous electrophysiological evidence indicates that this reinnervation is functional. The high specificity with which sprouting olivary axons reinnervate the proximal Purkinje cell dendrites suggests the existence of precise interactions between the growing fibres and their target. This example of "homotypic" collateral sprouting and reinnervation may thus provide a useful model for the study of nerve-target interactions.

Trimethyltin increases choline acetyltransferase in rat hippocampus

The environmental neurotoxin trimethyltin (TMT) destroys parts of the hippocampal formation as well as the entorhinal cortex but leaves the septal cholinergic projection to the hippocampus and dentate gyrus intact. In this study we measured choline acetyltransferase (ChAT) activity in micropunch samples of the dentate gyrus, the CA1 region of Ammon's horn, and the caudate-putamen as a measure of density of cholinergic innervation in control rats and rats exposed to 7 mg/kg TMT by means of gastric intubation. Three months after the rats were exposed to a single dose of TMT both the dentate gyrus and CA1 demonstrated significantly higher ChAT activity in TMT-exposed rats than in control rats. No differences were found between groups for the caudate-putamen samples. These results support the hypothesis that exposure to TMT causes reactive synaptogenesis in the cholinergic septohippocampal system.

Cloning of hippocampal poly(A) RNA sequences that increase after entorhinal cortex lesion in adult rat

Evidence is given for altered gene expression in the hippocampus in response to entorhinal cortex lesioning. Three RNA markers encoding glial fibrillary acidic protein, apolipoprotein E and alpha-tubulin were isolated from a rat hippocampal cDNA library by differential screening with cDNA probes from entorhinal cortex lesioned and control rat hippocampus RNA. By Northern blot analysis, mRNA for apolipoprotein E and alpha-tubulin increased to peak around 6 days after the lesion and returned to near control level at 30 days. The increased synthesis of both mRNAs coincides with the acute phase of synaptogenesis, protein synthesis, and polyribosomes accumulation in the deafferented hippocampal area.

Increases in transforming growth factor-beta mRNA in hippocampus during response to entorhinal cortex lesions in intact and adrenalectomized rats

Transforming growth factor-beta mRNA was detected with a rat TGF-beta 1 coding sequence probe as a 2.5 kb band by RNA blot hybridization of total RNA from the adult male rat hippocampus. Following electrolytic lesions of the entorhinal cortex that cause hippocampal deafferentation and synaptic remodeling, TGF-beta mRNA increases 5-fold in ipsilateral hippocampus when compared with intact controls. This increase was independent of prior adrenalectomy or corticosterone-replacement. These data demonstrate that TGF-beta gene expression increases in response to hippocampal deafferentation.

Neural transplantation: an historical perspective

Literature on transplantation of neural and nonneural tissues into the brains of host animals is reviewed in the perspective of various issues. The two dominant issues determining this research were elucidation of embryological processes underlying the development of the nervous system and regeneration in the host brain. A comprehensive review of studies on regeneration in the central nervous system (CNS), using this technique of transplantation, indicates that regeneration of axonal fibers is small in magnitude and extent, and that it is more directly related to the trauma caused to the brain than to any other variable. This literature review attempts to provide a perspective to the contemporary research on neural transplantation and on regeneration in the CNS.

Effects of MK-801 upon local cerebral glucose utilisation in conscious rats following unilateral lesion of caudal entorhinal cortex

Local cerebral glucose utilisation was examined in 62 discrete regions of conscious rats following unilateral ibotenic acid lesion of the caudal entorhinal cortex, and subsequent pharmacological challenge with (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (MK-801), a non-competitive N-methyl-D-aspartate (NMDA) receptor antagonist. Fourteen days after unilateral lesion of the entorhinal cortex, there were no significant alterations in local cerebral glucose use except within the lesioned entorhinal cortex (reduced by 31% compared to sham-operated control animals). In sham-operated animals, systemic administration of MK-801 (0.5 mg/kg, i.v.) induced anatomically organised alterations in glucose use with increases in olfactory areas, subicular complex and some limbic areas (posterior cingulate cortex, mammillary body and anteroventral thalamic nucleus), and decreases in the inferior colliculus and neocortex (auditory, sensory-motor, somatosensory and frontal cortices). In animals with unilateral entorhinal cortex lesions, the metabolic response to MK-801 differed significantly from the response to the drug in sham-lesioned animals in a number of regions, viz. hippocampus, molecular layer (ipsilateral to lesion), entorhinal cortex (ipsilateral), dentate gyrus (ipsilateral), presubiculum (bilateral), parasubiculum (bilateral) and nucleus accumbens (bilateral). The ability of MK-801 to reduce glucose use in the neocortex was not altered by entorhinal cortex lesion. These data suggest that the functional consequences of non-competitive NMDA receptor blockade are dependent in some areas upon the integrity of the perforant pathway from the entorhinal cortex to the hippocampus.

Cholinergic sprouting in the hippocampus: a proposed role for IL-1

Damage to the entorhinal afferents (i.e., perforant path) to the hippocampal dentate gyrus leads to sprouting of the remaining intact septal cholinergic afferents within the denervated outer molecular layer. To investigate the cellular and molecular events which may contribute to this sprouting response, we describe the temporal sequence of cellular changes in the denervated zone prior to the observed neural reorganization. Rats were given perforant path (PP) transections and sacrificed at various time points following the lesion, on Days (D) 1, 2, 3, 4, 5, 6, and 30. Coronal sections at the level of the dorsal hippocampus were immunostained to localize microglia (OX-42), interleukin-1 (IL-1), and astroctytes (GFAP). We observed a rapid increase in the number of immunoreactive microglia in the denervated molecular layer within the first day following PP transection. Parallel sections show a concomitant increase in the number of IL-1-positive cells. Maximal reactive changes (i.e., hypertrophy and increase in number) in GFAP-positive astrocytes are not observed until D5. This time course of events suggests a role of microglia in astrocyte activation in vivo via production of IL-1 and offers support for a proposed hypothesis postulating a cascade of glial events which may lead to cholinergic sprouting following PP transection.

Long-term administration of mouse nerve growth factor to adult rats with partial lesions of the cholinergic septohippocampal pathway

Nerve growth factor (NGF), a neurotrophic factor acting on cholinergic neurons of the basal forebrain, has been proposed as a treatment for Alzheimer's disease. Experimental support for its pharmacological use is derived from short-term studies showing that intraventricular administration of NGF during 2-4 weeks protects cholinergic cell bodies from lesion-induced degeneration, stimulates synthesis of choline acetyltransferase, and improves various behavioral impairments. To investigate the consequences of long-term NGF administration, we tested whether cholinergic cell bodies are protected from lesion-induced degeneration and whether cholinergic axons are stimulated to regrow into the denervated hippocampus following fimbrial transections. We found that intraventricular injections of NGF twice a week for 5 months to adult rats resulted in extended protection of cholinergic cell bodies from lesion-induced degeneration and did not produce obvious detrimental effects on the animals. NGF treatment mildly stimulated growth of cholinergic neurites within the 2-mm area directly adjacent to the fimbrial lesion but it failed to induce significant homotypic growth of cholinergic neurites into the deafferented hippocampus.

Hippocampal muscarinic supersensitivity after AF64A medial septal lesion excludes M1 receptors

Stereotaxic injection of AF64A, into the medial septum of the rat, resulted in significant loss of presynaptic cholinergic markers in this structure. No significant change was observed for the presynaptic neuronal markers for dopamine- and serotonin-containing neurons in either the medial septum or hippocampus. The AF64A lesion also resulted in a significant reduction of muscarinic receptors as demonstrated by a loss of [3H]QNB binding in the medial septum. Subtype analysis showed the decrease of receptor binding in the medial septum to be due to a loss of M1 receptors as well as other muscarinic receptor subtypes. In the hippocampal formation, [3H]hemicholinium-3 binding was significantly reduced in the molecular layer of the dentate gyrus, and in the stratum oriens and stratum radiatum of the hippocampus. AF64A lesion resulted in a significant increase (Bmax) in non-M1 muscarinic receptors in hippocampal stratum oriens, in areas CA2, CA3, and CA4. AF64A lesion of the medial septum did not result in muscarinic receptor alterations in any other region of the hippocampal formation examined. These results indicate that postsynaptic muscarinic receptors in the stratum oriens of the CA2 to CA4 region of the hippocampus mediate primarily the function of the cholinergic cell bodies of the medial septum. These receptors are not of the M1 subtype.