beta-amyloid neurotoxicity is mediated by a glutamate-triggered excitotoxic cascade in rat nucleus basalis

Whereas a cardinal role for beta-amyloid protein (Abeta) has been postulated as a major trigger of neuronal injury in Alzheimer's disease, the pathogenic mechanism by which Abeta deranges nerve cells remains largely elusive. Here we report correlative in vitro and in vivo evidence that an excitotoxic cascade mediates Abeta neurotoxicity in the rat magnocellular nucleus basalis (MBN). In vitro application of Abeta to astrocytes elicits rapid depolarization of astroglial membranes with a concomitant inhibition of glutamate uptake. In vivo Abeta infusion by way of microdialysis in the MBN revealed peak extracellular concentrations of excitatory amino acid neurotransmitters within 20-30 min. Abeta-triggered extracellular elevation of excitatory amino acids coincided with a significantly enhanced intracellular accumulation of Ca2+ in the Abeta injection area, as was demonstrated by 45Ca2+ autoradiography. In consequence of these acute processes delayed cell death in the MBN and persistent loss of cholinergic fibre projections to the neocortex appear as early as 3 days following the Abeta-induced toxic insult. Such a sequence of Abeta toxicity was effectively antagonized by the N-methyl-D-aspartate (NMDA) receptor ligand dizocilpine maleate (MK-801). Moreover, Abeta toxicity in the MBN decreases with advancing age that may be associated with the age-related loss of NMDA receptor expression in rats. In summary, the present results indicate that Abeta compromises neurons of the rat MBN via an excitotoxic pathway including astroglial depolarization, extracellular glutamate accumulation, NMDA receptor activation and an intracellular Ca2+ overload leading to cell death.     

Factors governing the potentiation of NMDA receptor-mediated responses in hippocampus.

A modified medium containing an AMPA receptor antagonist and low concentrations of magnesium was used to investigate the factors governing the potentiation of synaptic responses mediated by NMDA receptors. When long-term potentiation (LTP) was induced in standard medium and NMDA responses were analyzed by changing to the modified medium, no statistically significant differences were observed between potentiated and control pathways. Returning the slices to the standard medium showed that LTP was still present, indicating that the potentiation effect was not reversed by the modified medium. High-frequency stimulation applied in the modified medium produced an enhancement of synaptic responses, but this was not occluded by prior potentiation in standard medium. The degree of potentiation induced in the modified medium and expressed by NMDA responses was larger in the presence than in the absence of inhibition and, unlike LTP, was proportionately larger when recorded in the stratum pyramidale than in the stratum radiatum. These results indicate that the potentiation of NMDA receptor-mediated responses triggered by high-frequency stimulation applied in modified medium differs in several respects from the LTP induced in standard conditions. They confirm that LTP is expressed to a markedly different degree by NMDA and non-NMDA receptors and suggest that events that do not necessarily accompany LTP affect the potentiation of NMDA receptor-dependent synaptic responses.     

Hypothesis regarding the cellular mechanisms responsible for long-term synaptic potentiation in the hippocampus

A possible cellular mechanism accounting for the long-term potentiation (LTP) of synaptic transmission in the hippocampus is presented. Our multiple-stage hypothesis postulates that repetitive stimulaion causes an increase of intracellular calcium in the target dendritic regions which results in the activation of a membrane-associated protease which in turn exposes additional glutamate receptors.     

Use-dependent modification of a slow NMDA receptor-mediated synaptic potential in rat amygdalar slices

A single stimulus applied to the endopyriform nucleus evoked in 35 of the 101 basolateral amygdaloid (BLA) neurons a slow excitatory postsynaptic potential (s-EPSP) of varying latencies. The s-EPSP could be graded by changing the stimulus intensity and, on reaching the threshold, triggered action potentials. At stimulus intensity just subthreshold for evoking a spike, the s-EPSP has an average amplitude of 16.3 ± 1.4 mV, a time to peak of 25.7 ± 3.8 ms, and a duration of 124 ± 14 ms. The s-EPSP was reversibly blocked by DL-2-amino-5-phosphonovaleate (DLAPV) or ketamine, indicating its mediation through N-methyl-D-aspartate (NMDA) receptor activation. However, the s-EPSP was not able to follow stimulus frequency of 1 Hz, suggesting that APV-sensitive s-EPSP is probably generated by a polysynaptic pathway. The s-EPSP was greatly enhanced by synaptic stimulation in the presence of bicuculline or in Mg⁺⁺-free solution leading to the genesis of paroxysmal depolarizing shift (PDS). The s-EPSP can undergo robust long-term potentiation (LTP) following tetanic stimulation. These results suggest that the NMDA receptor-mediated s-EPSP may play an important role in epileptogenesis and synaptic plasticity in the amygdala. © 1993 Wiley-Liss, Inc.     

Hydroxysafflor yellow A improves learning and memory in a rat model of vascular dementia by increasing VEGF and NR1 in the hippocampus

Hydroxysafflor yellow A (HSYA) has angiogenesisregulating and neuro-protective effects, but its effects on vascular dementia (VaD) are unknown. In this study, 30 adult Sprague-Dawley rats were randomly allocated to five groups: normal, sham-operation, VaD alone (bilateral carotid artery occlusion), VaD plus saline (control), and VaD plus HSYA. One week after operation, the HSYA group received one daily tail-vein injection of 0.6 mg/100 g HSYA for two weeks. Five weeks after operation, the spatial memory of all five groups was evaluated by the water maze task, and synaptic plasticity in the hippocampus was assessed by the long-term potentiation (LTP) method. Vascular endothelial growth factor (VEGF) and N-methyl-Daspartic acid receptor 1 (NR1) expression in the hippocampus was detected via Western blot. We found that, compared with the group with VaD alone, the group with HSYA had a reduced escape latency in the water maze (P < 0.05), and the LTP at CA3-CA1 synapses in the hippocampus was enhanced (P < 0.05). Western blot in the late-phase VaD group showed slight up-regulation of VEGF and downregulation of NR1 in the hippocampus, while HSYA significantly up-regulated both VEGF and NR1. These results suggested that HSYA promotes angiogenesis and increases synaptic plasticity, thus improving spatial learning and memory in the rat model of VaD.     

Impairment of long-term potentiation in rat hippocampus following chronic ethanol treatment

The effect of chronic ethanol treatment on long-term potentiation (LTP), a possible substrate for memory, was studied in rats using the in vitro hippocampal slice preparation. Rats were provided ad libitum access to an ethanol-containing or control liquid diet. One group of animals received the diet for a total period of 9 months before testing, while a second group received the diet for 7 months and was allowed a 2 month ethanol-free period before testing. LTP was induced in the CA1 region by orthodromic stimulation of the stratum radiatum with 4 stimulus trains of 200 pulses each at 25, 50, 100 and 200 Hz separated by 10 min intervals. The number of slices with potentiation greater than 15% was significantly smaller in the ethanol-fed animals both before and following the 2 month withdrawal period. However, the average percent increase in the amplitude of the population spike was significantly decreased in the ethanol-fed animals when tested before withdrawal but no significant difference was detected following the 2 month withdrawal period, suggesting some recovery. The possible mechanisms mediating the chronic ethanol-induced depression of LTP are discussed.     

Posttraining changes in excitability of the commissural path-CA1 pyramidal cell synapse in the hippocampus of mice

Mice were partially trained on a bar-press operant conditioning task on continuous reinforcement (CRF). The amplitude of population excitatory postsynaptic potentials (EPSPs) evoked by commissural stimulation of the CA1 field of the dorsal hippocampus was found to significantly increase 1 h after training and then to decrease. This phenomenon was either not observed or much less evident in mice which could not learn the task or which had already been trained on this task.     

Synaptic correlates of associative potentiation/depression: an ultrastructural study in the hippocampus

Brief high-frequency trains delivered to the monosynaptic entorhinal cortical input to the dentate gyrus result in both increases and decreases of synaptic strength as a function of whether a particular afferent is active during conditioning (associative potentiation/depression^{15, 30}). The present report concerns the effect such brief, high-frequency conditioning trains upon the asymmetric synapses of the rat dentate gyrus molecular layer. Only those animals whose responses increased at least 50% following conditioning stimulation were included in the study. Additional animals were used for one-dimensional current source density analyses to localize the activated synaptic region. Double blind scoring procedures were used to classify and quantify electron micrographic data. Asymmetric synapses were scored as a function of their position in the molecular layer, spine head size and shape, and postsynaptic density length. All data were treated as inherently matched comparisons between the conditioned and control sides of each animal. The number of large, concave spine synapses with large postsynaptic densities significantly increases in the central zone of synaptic activation. Bordering this zone are regions with increases in synaptic number following conditioning, primarily due to an increased number of small spine synapses. The increased number of large, concave spine synapses in the central zone is postulated to mediate associative potentiation. The many small spine heads just adjacent to the zone of strongest synaptic activation may reflect synaptic depression evoked at synapses inactive during conditioning.     

Selective effects of aniracetam across receptor types and forms of synaptic facilitation in hippocampus.

Aniracetam reversibly increased synaptic responses mediated by the AMPA but not the NMDA subclass of glutamate receptors in hippocampus and was considerably more potent than structurally similar nootropics. The drug had greater effects on field excitatory postsynaptic potentials (EPSPs) in the dentate gyrus and CA1 region than it did in the CA3 region, suggesting that it differentiates between variants of the AMPA receptor. Ligand binding to glutamate receptors in synaptosomal membrane fractions was minimally changed by aniracetam. Finally, the percent facilitation produced by aniracetam in the CA1 region was not reduced by any of three treatments (4-aminopyridine, changes in extracellular calcium concentrations, paired-pulse stimulation) that affect release but, in accord with a previous report, was substantially decreased by long-term potentiation. These results support the conclusion that aniracetam selectively increases the conductance of a subgroup of synaptic AMPA receptors in hippocampus and suggest that receptor changes underlie the expression of long-term potentiation.     

Immunocytochemical localization of GABA-, cholecystokinin-, vasoactive intestinal polypeptide-, and somatostatin-like immunoreactivity in the area dentata and hippocampus of the rat

Hippocampal neurons containing GABA-, cholecystokinin(CCK)-, vasoactive intestinal polypeptide(VIP)-, or somatostatin(SS)-like immunoreactivity (LI) were localized in sections of rat hippocampus. GABA-, CCK-, VIP, and SS-LI are found exclusively in interneurons of the area dentata and hippocampus. In the area dentata, GABA-LI occurs in cells of all strata but predominates in type 1 and 2 basket cells. CCK-LI is present in a subset of these basket cells and some hilar cells. VIP-LI is present in a distinct subset of dentate interneurons that, unlike the type 1 and 2 basket cells, do not contribute to the fiber plexus in the inner molecular layer. These VIP-LI interneurons send their axons to nearby granule cells and form a plexus in the hilus. SS-LI, although rare in cells of the molecular and granular layers, is present in a large population of hilar interneurons that do not exhibit GABA-, CCK-, or VIP-LI. In area CA3 of the hippocampus, a variety of morphologically diverse interneurons containing GABA-, CCK-, VIP-, or SS-LI are present in all strata. In area CA1, SS-LI is present mainly in cells of strata oriens and pyramidale. GABA- CCK- and VIP-LI interneurons are present in all strata of CA1 but, unlike the SS-LI cells, are most numerous in strata pyramidale and radiatum. These findings in the area dentata, taken together with those of Kosaka et al. (J. Comp. Neurol. 239:967-969, '85), indicate that two main populations of interneurons can be discriminated on the basis of the substances they contain. One is a group of GABA-LI cells, some of which also contain CCK- and/or VIP-LI. These cells innervate the granule cells and the second group of interneurons, the SS-LI hilar cells, which apparently form part of the dentate ipsilateral associational/commissural projections.     

Low-frequency stimulation of the direct cortical input to area CA1 induces homosynaptic LTD and heterosynaptic LTP in the rat hippocampal-entorhinal cortex slice preparation

The entorhinal cortex (EC) innervates area CA1 and the subiculum directly via the portion of the perforant path, which originates from EC layer III cells referred to as direct cortical input (dCI), and indirectly via the trisynaptic loop through the dentate gyrus and area CA3. The dCI is of great importance as it mediates positional information for activation of place cells that is not prevented after interrupting information flow from area CA3 to CA1. In this study, we investigated the effects of low-frequency stimulation of the dCI on homo- and heterosynaptic plasticity in area CA1 and tested for the contribution of NMDA, GABA(A), GABA(B), kainate and group I mGlu receptors. We demonstrate that 1 Hz stimulation of the dCI induces homosynaptic long-term depression (LTD) and that 1 Hz stimulation of the dCI induces a long-lasting augmentation of stratum radiatum-induced population spikes in area CA1 (heterosynaptic long-term potentiation). Additionally we show that homosynaptic effects depend on activation of GABA(B) and kainate receptors, whereas the heterosynaptic effects are GABA(A) and mGlu receptor dependent.     

GABAergic nonpyramidal neurons in intracerebral transplants of the rat hippocampus and fascia dentata: a combined light and electron microscopic immunocytochemical study

Glutamate decarboxylase (GAD) immunocytochemistry was used to study GABAergic neurons and synapses in intracerebral allografts of the rat hippocampus and fascia dentata. Tissue blocks of regio inferior of Ammon's horn (hippocampal field CA3) or of the fascia dentata were taken from newborn rats and transplanted to the hippocampal region of young adult rats. After 6 1/2 months' survival the recipient brains were fixed by perfusion and serially sectioned on a Vibratome. Sections containing the transplant and/or the host hippocampal region were immunostained for GAD and flat-embedded in Araldite for a correlated light and electron microscopic analysis. Immunostained neurons and terminals in the transplants were compared to immunoreactive elements in the hippocampus and fascia dentata of the hosts and other, normal rats. As in the hippocampal formation in situ, GAD-immunoreactive neurons and terminals in the transplants were observed in all layers. In dentate transplants a preponderance of immunostained cells was found just beneath the granule cell layer. In both hippocampal and dentate transplants, immunoreactive terminals were most abundant in the cell layers where they formed characteristic pericellular baskets around the pyramidal and granule cell bodies. In the electron microscope, the transplant GAD-immunoreactive neurons exhibited numerous cytoplasmic organelles, deeply infolded nuclei, and nuclear rods. Immunoreactive terminals formed symmetric synaptic contacts on the cell bodies, dendritic shafts, and spines of transplant pyramidal cells, granule cells, and hilar neurons. These are normal characteristics of GAD-immunoreactive neurons and terminals as also observed in the hippocampus of the host rats and the normal controls. Our results demonstrate that GABAergic neurons survive transplantation and develop a cell-specific morphology that includes the axonal projections.     

Autonomous activity of CaMKII is only transiently increased following the induction of long-term potentiation in the rat hippocampus

A major role has been postulated for a maintained increase in the autonomous activity of CaMKII in the expression of long-term potentiation (LTP). However, attempts to inhibit the expression of LTP with CaMKII inhibitors have yielded inconsistent results. Here we compare the changes in CaMKII autonomous activity and phosphorylation at Thr286 of alphaCaMKII in rat hippocampal slices using chemical or tetanic stimulation to produce either LTP or short-term potentiation (STP). Tetanus-induced LTP in area CA1 requires CaMKII activation and Thr286 phosphorylation of alphaCaMKII, but we did not observe an increase in autonomous activity. Next we induced LTP by 10 min exposure to 25 mM tetraethyl-ammonium (TEA) or 5 min exposure to 41 mM potassium (K) after pretreatment with calyculin A. Exposure to K alone produced STP. These protocols allowed us to monitor temporal changes in autonomous activity during and after exposure to the potentiating chemical stimulus. In chemically induced LTP, autonomous activity was maximally increased within 30 s whereas this increase was significantly delayed in STP. However, in both LTP and STP the two-fold increase in autonomous activity measured immediately after stimulation was short-lived, returning to baseline within 2-5 min after re-exposure to normal ACSF. In LTP, but not in STP, the phosphorylation of alphaCaMKII at Thr286 persisted for at least 60 min after stimulation. These results confirm that LTP is associated with a maintained increase in autophosphorylation at Thr286 but indicate that a persistent increase in the autonomous activity of CaMKII is not required for the expression of LTP.     

Axo-axonic chandelier cells in the rat fascia dentata: Golgi-electron microscopy and immunocytochemical studies.

Synaptic transmission can be blocked very efficiently by inhibitory synapses on axon initial segments. Inhibitory chandelier cells forming synapses on the axon initial segment of pyramidal neurons have been found in the neocortex and hippocampus proper. Here we describe an axo-axonic local circuit neuron in the rat fascia dentata that establishes synaptic contacts with axon initial segments of numerous dentate granule cells. Examination of a large number of Golgi-impregnated nongranule cells in the fascia dentata of rats revealed a group of neurons with characteristics of chandelier cells. Thus these cells exhibited an extensive axonal plexus within the granular layer that characteristically formed vertical aggregations of axonal varicosities. The cell bodies of these neurons were located in the inner molecular layer or in the outer part of the granular layer. Their dendrites invaded the molecular layer, suggesting an afferent innervation similar to that of the granule cells. Well impregnated putative axo-axonic cells were gold-toned for an electron microscopic analysis. The cell bodies and dendrites of these neurons exhibited characteristic ultrastructural features of nongranule cells, i.e., large amounts of perinuclear cytoplasm, infoldings of the nuclear membrane, and a large number of synaptic contacts on the perikaryon and on the smooth dendritic shafts. The axon originating from the cell body or from a proximal dendrite gave rise to numerous vesicle-filled varicosities that almost exclusively formed symmetric synaptic contacts with axon initial segments. A semiquantitative study of five axonal complexes demonstrated that 92.3% of identified postsynaptic elements were initial segments of granule cell axons. Immunostaining with antibodies against glutamate decarboxylase (GAD) and parvalbumin (PARV) revealed a subpopulation of neurons that very much resembled the Golgi-impregnated axo-axonic cells with regard to cell body location, dendritic arborization, and fine structural characteristics of perikarya and dendrites. GAD and PARV were found to be coexistent in these cells. Moreover, we found GAD- and PARV-immunoreactive terminals in symmetric synaptic contact with axon initial segments of granule cells. The present study has shown a hitherto unknown axo-axonic cell in the rat fascia dentata. On the basis of our immunocytochemical findings, we hypothesize that this cell exerts a strong inhibitory effect on dentate granule cells. This way, signal transmission from the fascia dentata to the hippocampus proper within the "trisynaptic pathway" can efficiently be controlled by a group of highly specialized neurons.     

Distinct mechanisms of bidirectional activity-dependent synaptic plasticity in superficial and deep layers of rat entorhinal cortex

The entorhinal cortex plays a key role in processing memory information in the brain; superficial layers relay information to, and deep layers receive information from, the hippocampus. The cellular mechanisms of memory are thought to include a number that produce long-term potentiation (LTP) and depression (LTD) of synaptic strength. Our work presents evidence that LTP and LTD occur simultaneously at memory-relevant synapses. We report here that low frequency stimulation generates NMDA receptor-dependent LTD in Wistar rat superficial (layers II and III), and LTP in the deep entorhinal cortex layers (layers V and VI). LTP in deep layers is masked by simultaneously occurring voltage-gated calcium channel-dependent LTD. Our data support a novel mechanism for the sliding-threshold (BCM) model of synaptic plasticity: The sliding thresholds for induction of LTP and LTD in entorhinal cortex deep layers will be driven by the relative activation state of NMDA receptors and voltage-gated calcium channels. The co-expression of LTD and LTP at presynaptic sites in the entorhinal cortex deep layers reveals an intriguing mechanism for differential processing of synaptic information, which may underlie the vast dynamic capacity for information storage by this cortical structure.     

Continuous white noise exposure during and after auditory critical period differentially alters bidirectional thalamocortical plasticity in rat auditory cortex in vivo

Long-term potentiation (LTP) and long-term depression are thought to mediate activity-dependent brain plasticity but their role in the development of the thalamocortical auditory system in vivo has not been investigated. In adult urethane-anaesthetized rats, theta-burst stimulation of the medial geniculate nucleus produced robust LTP (40% amplitude enhancement) of field post-synaptic evoked potentials recorded in the superficial layers of the primary auditory cortex. Low-frequency (1-Hz) stimulation resulted in transient depression ( approximately 40%) of field post-synaptic evoked potential amplitude. Both LTP and synaptic depression were found to be dependent on cortical N-methyl-d-aspartate receptors. Thalamocortical plasticity was also assessed after continuous white noise exposure, thought to arrest auditory cortex maturation when applied during the critical period of post-natal primary auditory cortex development. Rats housed in continuous white noise for the first 50 days of post-natal life exhibited greater LTP ( approximately 80%) than controls reared in unaltered acoustic environments. The protocol used to elicit depression also resulted in substantial LTP ( approximately 50%) in white noise-reared animals. Adults housed in white noise for the same length of time exhibited normal LTP but displayed greater and persistent levels of synaptic depression ( approximately 70%). Thus, the absence of patterned auditory stimulation during early post-natal life appears to retard sensory-dependent thalamocortical synaptic strengthening, as indicated by the preferential readiness for synaptic potentiation over depression. The fact that the same auditory manipulation in adults results in synapses favouring depression demonstrates the critical role of developmental stage in determining the direction of synaptic modification in the thalamocortical auditory system.     

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

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

Corticotrophin‐releasing factor produces a long‐lasting enhancement of synaptic efficacy in the hippocampus

We have previously demonstrated that intra-hippocampal injection of corticotrophin-releasing factor improved memory retention of an inhibitory avoidance learning in rats; while the electrophysiological effects corticotrophin-releasing factor produces on hippocampal neurons are largely uncharacterized. In the present study, we found that corticotrophin-releasing factor injected into the dentate gyrus of hippocampus produced a dose-dependent and long-lasting enhancement in synaptic efficacy of these neurons, as measured by an increase in the amplitude and slope of population excitatory postsynaptic potentials, as well as the amplitude of population spike. The onset of corticotrophin-releasing factor-induced potentiation was slow. It was observed approximately 40–60 min after corticotrophin-releasing factor administration and lasted for more than 5 h. This effect of corticotrophin-releasing factor was blocked by pretreatment with the cyclase-adenosine-3,5-monophosphate (cAMP) inhibitor Rp-adenosine-3,5-cyclic monophosphothiolate triethylamine (Rp-cAMPS) and partially blocked by the N-methyl-D-aspartate receptor antagonist MK-801. Further, pretreatment with corticotrophin-releasing factor receptor antagonist dose-dependently diminished tetanization-induced long-term potentiation, and corticotrophin-releasing factor and tetanic stimuli had an additive effect on hippocampal neuron excitation. Moreover, direct injection of corticotrophin-releasing factor increased cAMP level in the dentate gyrus. These results together suggest that corticotrophin-releasing factor-induced potentiation simulates the late phase of tetanization-induced long-term potentiation and cAMP seems to be the messenger mediating this effect. Moreover, corticotrophin-releasing factor-induced potentiation and long-term potentiation may share some similar mechanisms, and corticotrophin-releasing factor is probably involved in the neural circuits underlying long-term potentiation. Thus, corticotrophin-releasing factor may play an important role in modulating synaptic plasticity in the hippocampus.