The biochemistry of memory: a new and specific hypothesis

Murine trisomy 16 model of Down's syndrome: central nervous system electron microscopic observations

Murine trisomy 16 is an excellent model for the human Down's syndrome (DS). Electron microscopic (EM) observations were made of the cortical plate within the developing telencephalic vesicle at the gestational age of E17. The EM observations revealed: (A) microtubular profiles which were more coiled and curved in the trisomic condition; (B) poor cell-to-cell apposition and increased cellular membrane fragmentation in trisomy 16; (C) increased nuclear contour irregularity in trisomic neurons; (D) significant decrease in the cross-sectional area of neuronal nuclei in trisomy 16 (p less than 0.01). The microtubular observations lend credence to the hypothesis that abnormal cytoskeletal interactions may underlie the mental deficiency seen in DS and may predispose to the eventual development of Alzheimer's disease (AD) in DS individuals. The cellular membrane findings may be related to reported CNS membrane lipid abnormalities in DS. The nuclear morphologic observations may be related to the reported differences in chromatin and nuclear histone expression in AD. These results strengthen the role of the trisomy 16 mouse as a model for DS and potentially for AD.

Ankyrin links fodrin to the alpha subunit of Na,K-ATPase in Madin-Darby canine kidney cells and in intact renal tubule cells

In nonerythroid cells the distribution of the cortical membrane skeleton composed of fodrin (spectrin), actin, and other proteins varies both temporally with cell development and spatially within the cell and on the membrane. In monolayers of Madin-Darby canine kidney (MDCK) cells, it has previously been shown that fodrin and Na,K-ATPase are codistributed asymmetrically at the basolateral margins of the cell, and that the distribution of fodrin appears to be regulated posttranslationally when confluence is achieved (Nelson, W. J., and P. I. Veshnock. 1987. J. Cell Biol. 104:1527-1537). The molecular mechanisms underlying these changes are poorly understood. We find that (a) in confluent MDCK cells and intact kidney proximal tubule cells, Na,K-ATPase, fodrin, and analogues of human erythrocyte ankyrin are precisely colocalized in the basolateral domain at the ultrastructural level. (b) This colocalization is only achieved in MDCK cells after confluence is attained. (c) Erythrocyte ankyrin binds saturably to Na,K-ATPase in a molar ratio of approximately 1 ankyrin to 4 Na,K-ATPase's, with a kD of 2.6 microM. (d) The binding of ankyrin to Na,K-ATPase is inhibited by the 43-kD cytoplasmic domain of erythrocyte band 3. (e) 125I-labeled ankyrin binds to the alpha subunit of Na,K-ATPase in vitro. There also appears to be a second minor membrane protein of approximately 240 kD that is associated with both erythrocyte and kidney membranes that binds 125I-labeled ankyrin avidly. The precise identity of this component is unknown. These results identify a molecular mechanism in the renal epithelial cell that may account for the polarized distribution of the fodrin-based cortical cytoskeleton.

Epilepsy: relationships between electrophysiology and intracellular mechanisms involving second messengers and gene expression

It is well known that pure absence epilepsy is a benign form of seizure disorder, while most others, particularly partial and convulsive seizures may have transient or permanent deleterious consequences and are more difficult to bring under therapeutic control by anticonvulsants. The hypothesis is proposed that the preservation of GABA-ergic inhibition in absence attacks and its breakdown in most other seizures may explain these differences. Breakdown of GABA-ergic inhibition allows NMDA receptors to become active. This opens the way for Ca2+ to enter the cell. Such Ca2+ entry is a long-lasting phenomenon. It is likely to be massive during most seizures except during absence attacks, and may therefore damage the neuron transiently or permanently. It may even destroy it. Ca2+ entry is also a crucial factor in the activation of the second messenger cascade which involves cytosolic as well as nuclear (genomic) components. Activation of this cascade converts short-lived electrophysiological processes occurring at the membrane into much longer-lasting intracellular processes. These may include plastic changes at the synaptic and receptor level and may account for kindling and the increasing therapy-resistance of long-standing seizure disorders. Changes resulting from massive Ca2+ entry into the neuron may explain why most seizures, except absence attacks, may have deleterious consequences of various kinds, some short-lived, some of longer duration, and some even permanent.

Muscarinic inhibition of endogenous glutamate release from rat hippocampus synaptosomes

The effects of acetylcholine (ACh) on the depolarization-evoked release of endogenous glutamic acid (Glu) have been studied using synaptosomes prepared from rat hippocampus and depolarized in superfusion with 15 mM KCl. Acetylcholine inhibited Glu release in a concentration-dependent way. The natural agonist was particularly effective causing 50% inhibition of Glu release at 10 microM in the absence of acetylcholinesterase (AChE) inhibitors. The inhibitory effect of ACh on the K+-evoked release of Glu was antagonized by the selective muscarinic receptor antagonist atropine but not by the nicotinic receptor antagonist mecamylamine. The data represent the first demonstration that muscarinic receptors located on Glu axon terminals in rat hippocampus may modulate the release of Glu.

New theory of hippocampal function: associated rehearsal of multiplexed coded symbols

A new theory of the role of the hippocampus in the selective storage of information in long-term memory is presented. This theory is based on the very recent discovery that neurons in the mammalian cerebral cortex transmit extremely precise copies of patterns of discharge in time when specific sensory inputs are presented, patterns that are interpreted to code for or symbolize specific items of information. The theory incorporates and provides an explanation for both the complex and unique internal structure of the hippocampal formation (the hippocampus and associated dentate gyrus) and the roles of many of the direct and indirect connections that structure makes with other brain structures. It also explains the deficits in learning that result from damage to the hippocampus and/or tracts that provide inputs to (or outputs from) this body as well as the role of the hippocampal formation in mapping the relationship of an individual to objects in its environment. The proposed enplanation is as follows. The hippocampal formation functions as a coordinated structure that, specifically, generates multiple copies of two different kinds of symbols (i.e., specific patterns of trains of nerve discharges in time). These two kinds of patterns are respectively provided by the entorhinal cortex through the perforant-alvear pathways and by the septal region, through the fornix, one of the two inputs to and the only output from the hippocampal formation. These two separate and different kinds of patterns are used to make multiplexed patterns that are ultimately transmitted to the cingulate gyrus and from there to other cortical memory storage locations. This transmission of amplified representations of different symbols occurs through the fornix. From there they are either transmitted to the mammilary bodies in the hypothalamus and from there to the anterior thalamic nuclei or, alternatively, directly to the anterior thalamic nuclei, bypassing the mammilary bodies. These thalamic nuclei in turn project the information to the cingulate gyrus of the cortex. The effect of the transmission of these mixtures of symbols is to cause the coordinated rehearsal and selective storage of relationships between separate inputs (specifically, patterns of discharge that symbolize different aspects of input) that are of probable significance to the survival of the system. The repeated presentation of such specific combinations of representations (symbols) then causes rehearsal-consolidation of these symbol associations as more permanent memories.(ABSTRACT TRUNCATED AT 400 WORDS)

The development of long-term potentiation in hippocampus and neocortex

The development of long-term potentiation (LTP), an enduring alteration in synaptic efficacy following afferent activation, was examined in CA1 hippocampus and primary visual cortex of rat. Both regions show little LTP prior to postnatal day 5, demonstrate a maximal potentiated response around postnatal day 15, and a subsequent decline to adult levels. These results are discussed with respect to the underlying mechanism of action and behavioral significance of these critical-period phenomena.

Long-term potentiation in the hippocampus of the anaesthetized rat is not associated with a sustained enhanced release of endogenous excitatory amino acids

The relationship between long-term potentiation of synaptic transmission and the release of endogenous glutamate and aspartate has been investigated in the CA1 region of the hippocampus and in the fascia dentata of the anaesthetized rat. A high-frequency train of electrical stimulation of afferent pathways produced a long lasting (greater than 2 h) enhancement of the field excitatory postsynaptic potential in CA1 and of the population spike in the fascia dentata. In both regions, this was not associated with a significant long lasting increase in the release of glutamate and aspartate. It is concluded that the maintenance of long-term potentiation is not associated with a sustained increase in the release of excitatory amino acids.

Synaptic structural plasticity: role of synaptic shape

Recent research has indicated that synaptic curvature is an important and potentially critical plastic feature of the synapse. Alterations in synaptic shape are related to synaptic function, being found both during maturation and in adulthood following neuronal activation. In this paper we review the evidence supporting synaptic shape as a plastic feature of synaptic structure. We also propose several mechanisms which might underlie these changes in shape. Finally, we suggest the possible functional role of alterations in synaptic curvature, including its potential in altering synaptic transmission efficacy.

Maintenance of long-term potentiation in rat dentate gyrus requires protein synthesis but not messenger RNA synthesis immediately post-tetanization

The involvement of new protein and messenger ribonucleic acid synthesis in long-term potentiation was studied in the anaesthetized rat dentate gyrus using several inhibitors of protein synthesis (anisomycin, emetine, cycloheximide and puromycin) and an inhibitor of messenger ribonucleic acid synthesis (actinomycin D). When injected for 1 h just prior to tetanization, the four inhibitors of protein synthesis produced a mild reduction of long-term potentiation of the excitatory postsynaptic potential measured 10 min after tetanization. Anisomycin produced a significantly faster decay of long-term potentiation, while the other inhibitors had more moderate effects. Actinomycin D failed to affect long-term potentiation. In a second experiment, the time-dependency of the anisomycin effect was examined. Anisomycin injected immediately after tetanization promoted decay of long-term potentiation, but when injected after a 15-min delay, the drug had no effect. Inhibition of protein synthesis for 4 h prior to tetanization did not have any more effect on long-term potentiation than inhibition for 1 h. In no experiment was long-term potentiation of the population spike affected by drug manipulation. These results suggest that for long-term potentiation of the excitatory postsynaptic potential to be maintained for at least 3 h proteins must be synthesized from already existing messenger ribonucleic acid, and that this synthesis is mostly completed within 15 min after tetanization.

Diversity of calcium ion channels in cellular membranes

Successful introduction of techniques for separation of different ionic currents and recording of single channel activity has demonstrated the diversity of membrane structures responsible for generation of calcium signal during various forms of cellular activity. In excitable cells the electrically-operated calcium channels have been separated into two types functioning in different membrane potential ranges (low- and high-threshold ones). The low-threshold channels are ontogenetically primary and may play a role in regulation of cell development and differentiation. A similar function may also be characteristic of chemically-operated channels in some highly specialized cells (lymphocytes). The high-threshold channels in excitable cells generate an intracellular signal coupling membrane excitation and intracellular metabolic processes responsible for specific cellular reactions (among them retention of traces of previous activity in neurons--"learning"--being especially important). Chemically-operated N-methyl-D-aspartate-channels also participate in this function. The calcium signal can be potentiated by activation of calcium-operated channels in the membranes of intracellular structures, resulting in the liberation of calcium ions from the intracellular stores. Although different types of calcium channels have some common features in their structure which may indicate their genetic similarity, their specific properties make them well suited for participation in a wide range of cellular mechanisms.

Rate-limiting step for transmission at excitatory synapses in hippocampus

To examine mechanisms that might be responsible for limiting transmission at excitatory synapses in hippocampus, we analyzed the relationship between extracellular calcium concentrations (1-6 mM) and postsynaptic responses in field CA1 of hippocampal slices using low stimulation intensities and a paired-pulse paradigm. Three effects were observed: One, the relationship between calcium levels and the slope (or amplitude) of the postsynaptic response was described by a sigmoidal function with an asymptote at about 4 mM. Double reciprocal pilots relating calcium concentration to the initial slope of EPSPs provided evidence for the cooperativity expected between calcium ions and transmitter release. Two, both the rise time and half-decay time of the postsynaptic responses were reduced with increasing calcium concentrations. These effects of calcium were more pronounced on the first response elicited by paired-pulse stimulation and were considerably attenuated by 2 microM bicuculline, indicating that feed-forward inhibition was positively related to calcium concentration and differentially activated by repetitive stimulation. However, inhibition was not responsible for the asymptotic relationship observed between calcium and response size. Three, while increasing the calcium concentration beyond 4 mM did not further affect the initial slope of excitatory postsynaptic potentials (EPSPs), paired-pulse facilitation and 4-aminopyridine were still effective in increasing response size. These results suggest 1) that neither the number of postsynaptic receptors nor the number of transmitter quanta available for release were limiting transmission as a function of the calcium concentration; and 2) that calcium entry into presynaptic terminals was likely to represent the limiting step under the conditions used.

Intrahippocampal colchicine injection results in spectrin proteolysis

Neurons in the hippocampal formation vary markedly in their susceptibility to colchicine toxicity. The present study was directed at evaluating the effects of colchicine on the proteolytic breakdown of the cytoskeletal protein spectrin within the hippocampus in the rat. Quantified by immunoblot analysis of spectrin breakdown products, the extent of proteolysis was found to correlate with the relative vulnerability of different hippocampal subfields to colchicine toxicity. Levels of breakdown products increased dramatically between 1 and 2 days after colchicine injection, peaked between 2 and 4 days, and remained detectably elevated for at least 35 days. Two days after colchicine injection, the spectrin breakdown products were significantly more concentrated in the molecular layer than in the granule cell/hilar region of the dentate gyrus. The colchicine-induced increase in spectrin breakdown products was significantly reduced by pretreatment with the protease inhibitor leupeptin and was significantly elevated by pretreatment with the lysosomal inhibitor chloroquine. Immunohistochemical analyses of the hippocampus at various times after colchicine injection revealed changes in the distribution of spectrin-like immunoreactivity that paralleled the changes observed by Western blot analysis. Thus increased staining was observed in the molecular layer of the dentate gyrus at 2 and 4 days after the injection, while staining in CA3 was only slightly increased. In addition, abnormal staining of reactive astrocytes was prominent at 2 days. The mechanism whereby colchicine results in neuronal death is as yet unknown. However, the results presented here demonstrate that extensive proteolysis of a cytoskeletal protein occurs in response to the drug, suggesting a plausible mechanism for its neurotoxicity. The protease responsible for the effect is likely to be calpain since the process is non-lysosomal, leupeptin-sensitive and produces spectrin breakdown products indistinguishable from those generated by calpain treatment in vitro. These data support the hypothesis that calpain-mediated degradation of cytoskeletal elements is a common and early response to neurodegenerative events and serves as a trigger in the development of various neuropathologies.

Acute ultrastructural response of hypoxic hypoxia with relative ischemia in the isolated brain

The acute cortical response to surgical brain isolation and subsequent extracorporal normoxic or 30 min hypoxic (PaO2 = 20 mm Hg) perfusions (hypoxic hypoxia with relative ischemia) was evaluated. Cerebral blood flow, arterial pH and CO2 were maintained constant during both perfusions; only the arterial oxygen content was changed. The isolated brain model used in this and previous investigations produces no qualitative ultrastructural changes in the neocortex following brain isolation and normoxic perfusion. However, the acute cortical structural response to 30 min of hypoxic hypoxia with relative ischemia demonstrated a number of important observations. Hypoxic hypoxia produced ultrastructural responses common to cerebral ischemia such as nuclear chromatin clumping, nucleolar condensation and cytoskeletal breakdown. Although neuronal abnormalities seen after 30 min of hypoxic hypoxia were similar to those acute neuronal changes observed following complete cerebral ischemia without recirculation, they differed three ways: (a) mitochondrial swelling and microvacuolation were observed in many cortical pyramidal neurons. (b) Glycogen particles within astroglial processes were observed even after a 30-min period of hypoxic hypoxia. (c) Perivascular astroglial swelling was minimal despite considerable perineuronal swelling. In contrast, incomplete cerebral ischemia produces mitochondrial changes similar to those in hypoxic hypoxia but also causes the depletion of tissue glycogen and perivascular glial swelling. Thus, hypoxic hypoxia with relative ischemia produces a unique acute ultrastructural response compared to either complete or incomplete cerebral ischemia.

Glycoprotein Synthesis Is Necessary for Memory of Sickness-Induced Learning in Chicks

Can current biochemical models of memory account for sickness-induced learning? We show that chicks can form an association between pecking a coloured but tasteless lure and becoming ill (LiCl, i.p.) 30 min later. We go on to demonstrate amnesia for this association, induced by intracranial administration of 2-deoxygalactose (10 micromole per hemisphere, in a 10 microl vol), an inhibitor of the synthesis of glycoproteins of the synaptic membrane, 10 min before pecking. Further, we show that this 2-deoxygalactose-induced amnesia is not state dependent. Thus the brain representation of the lure must be held, and require macromolecular syntheses, similar to those found in other forms of learning, for a considerable time before it can be associated with new significant experience. This is incompatible with contiguous synaptic firing views of memory.

Functional diversity among spectrin isoforms

The purpose of this review on spectrin is to examine the functional properties of this ubiquitous family of membrane skeletal proteins. Major topics include spectrin-membrane linkages, spectrin-filament linkages, the subcellular localization of spectrins in various cell types and a discussion of major functional differences between erythroid and nonerythroid spectrins. This includes a summary of studies from our own laboratories on the functional and structural comparison of avian spectrin isoforms which are comprised of a common alpha subunit and a tissue-specific beta subunit. Consequently, the observed differences among these spectrins can be assigned to differences in the properties of the beta subunits.

Presence of ghost doublets of coded neuronal patterns: relation to synaptic memory storage

Recent evidence demonstrates that controlled visual stimuli cause the generation, in the primary visual cortex of rhesus monkey cells, of large numbers of very precisely replicating copies of complex patterns of discharge consisting of three or more spikes, the patterns of which presumedly code for specific qualities of the stimuli presented. We present evidence that the copies of precisely replicating triplets of spikes, generally not exceeding 100 ms in duration, occur in close time proximity to many copies of highly precise "ghost" doublets. These doublets are defined as patterns consisting of two pulses, with precise separations in time, specifically those that would be generated if any one of the pulses making up a given replicating triplet were missing. In striking contrast, nonreplicating triplets (also present in these records)--that is, triplets made up of intervals that are not present in replicating triplets--are not accompanied by such ghost doublets. The persistence (memory) of capacity to produce such ghost doublets decays according to two independent kinetic rules. The first of these results in the disappearance of such doublets within about 0.1 s as measured by two independent methods, whereas the second disappears only after several minutes or longer. These results provide strong evidence consistent with the notion that at least some parts of the brain transmit, store representations of, and retrieve qualitative information through the use of a code consisting of specific patterns of nerve discharges in time.

Postnatal development of parvalbumin-, calbindin- and adult GABA-immunoreactivity in two visual nuclei of zebra finches

The characterization of neuron populations by their immunoreactivity against parvalbumin- and calbindin (28-kDa)-antisera has been used to study the postnatal development of the visual diencephalic nucleus rotundus and the mesencephalic nucleus isthmi complex in zebra finches. In nucleus rotundus, parvalbumin-immunoreactivity was restricted to the neuropil during the first 10 days and appears additionally in somata around day 12 where it remains until adulthood. Calbindin-immunoreactivity of the very scarce neuropil and the few somata, which can be observed during the first two weeks, disappears until adulthood. Thus, the adult nucleus rotundus shows an almost complementary distribution of calbindin- and parvalbumin-immunoreactive structures: the numerous, heavily parvalbumin-positive somata, which are surrounded by dense immunoreactive neuropil are in sharp contrast to the complete absence of calbindin-immunoreactive somata. Only a thin rim surrounding this nucleus contains punctate calbindin-positive neuropil. In the nucleus isthmi complex, parvalbumin and calbindin staining patterns show markedly different developmental profiles. While the density of parvalbumin-immunoreactive neuropil in the parvocellular part of the nucleus isthmi continuously increases and the somata remain unstained, the initially heavily calbindin-positive somata gradually lose their immunoreactivity during the first two weeks. In the adult nucleus isthmi complex, parvalbumin- and calbindin show nearly identical staining patterns. A comparison between the two calcium-binding proteins and GABA-immunoreactivity in adult brains revealed different relationships in the two nuclei: while in nucleus rotundus GABA-staining pattern neither resembles that of parvalbumin nor of calbindin, in the nucleus isthmi complex all three staining patterns coincide.

Mild stress stimulates rat hippocampal glucose utilization transiently via NMDA receptors, as assessed by lactography

Lactography is a novel technique that allows the continuous on-line registration of brain extracellular lactate in the freely behaving animal and that is based on a fluorimetric enzymatic assay of brain dialysates. Electroconvulsive shock, activation of the glutamate receptor (NMDA-type) and mild stress (immobilization, cold stress or handling) result in transient increases in the efflux of lactate from the rat hippocampus. The increase following immobilization stress was attenuated by the NMDA-receptor antagonist 2-amino-5-phosphopentanoic acid and after several pre-exposures to this stressor. These experiments suggest that mild stress activates glutamatergic neurons, which may be less after habituation to stress.

Loss of calbindin-28K immunoreactive neurones from the cortex in Alzheimer-type dementia

An antibody raised against chick intestinal calbindin D28K was used to study the number and size of calbindin immunoreactive neurones in postmortem human brains from neurologically normal controls and from patients with neuropathologically diagnosed Alzheimer-type dementia (ATD). In the controls, calbindin immunoreactive neurones were observed in all cerebral cortex areas examined including the frontal, temporal and parietal cortices. When compared with the controls, the number and size of calbindin immunoreactive neurones were significantly reduced in the cortices of patients with ATD. These findings suggest that calbindin containing neurones are affected in ATD.

A persistent postsynaptic modification mediates long-term potentiation in the hippocampus

Long-term potentiation (LTP) is a long-lasting enhancement of synaptic transmission that can be induced by brief repetitive stimulation of excitatory pathways in the hippocampus. One of the most controversial points is whether the process underlying the enhanced synaptic transmission occurs pre- or postsynaptically. To examine this question, we have taken advantage of the novel physiological properties of excitatory synaptic transmission in the CA1 region of the hippocampus. Synaptically released glutamate activates both NMDA and non-NMDA receptors on pyramidal cells, resulting in an excitatory postsynaptic potential (EPSP) with two distinct components. A selective increase in the non-NMDA component of the EPSP was observed with LTP. This result suggests that the enhancement of synaptic transmission during LTP is caused by an increased sensitivity of the postsynaptic neuron to synaptically released glutamate.

Age-dependent changes in murine protein kinase and protease enzymes

Hormone responsiveness is mediated by signal transduction mechanisms involving second messengers, such as cAMP and Ca2+, which regulate reversible changes in the phosphorylation state of proteins. During senescence individuals frequently exhibit a diminished responsiveness to hormones. We examined changes in enzymes involved in protein phosphorylation reactions that might account for this decreased adaptiveness in old mice, and observed the following post-maturational changes: (1) cAMP-dependent protein kinase (Pk-A) specific activity decreased in spleen cytosol and in the particulate fractions of lung, spleen and liver of 24-month-old mice as compared to 2-month-old mice. Splenic cytosolic Pk-A activity decreased by 18 months of age, while particulate activity decreased by 6 months; (2) The amount of 8-N3-[32P]cAMP, a photoaffinity analog of cAMP, incorporated into Pk-A regulatory (R)-subunits from spleen and liver particulate fractions decreased, while photolabeling of R-subunit degradative products with this analog in heart and spleen cytosol increased. (3) Age-dependent increases in membrane-associated protease activities were found in all organs, along with a decrease in cytosolic lung calpain activity. These proteolytic changes may account for the enhanced R-subunit degradation and decreased Pk-A activities observed during senescence. (4) Age-dependent alterations in Ca2+/phospholipid-dependent protein kinase (Pk-C) are organ specific: lung, liver, brain, and heart demonstrate no change in Pk-C activity, while spleen exhibits decreased activity. We hypothesize that these age-dependent alterations in kinase and proteolytic activities may be in part responsible for changes in cellular response to hormonal stimulation, differentiation signals, and antigen responsiveness during senescence.

Postsynaptic calcium is sufficient for potentiation of hippocampal synaptic transmission

Brief repetitive activation of excitatory synapses in the hippocampus leads to an increase in synaptic strength that lasts for many hours. This long-term potentiation (LTP) of synaptic transmission is the most compelling cellular model in the vertebrate brain for learning and memory. The critical role of postsynaptic calcium in triggering LTP has been directly examined using three types of experiment. First, nitr-5, a photolabile nitrobenzhydrol tetracarboxylate calcium chelator, which releases calcium in response to ultraviolet light, was used. Photolysis of nitr-5 injected into hippocampal CA1 pyramidal cells resulted in a large enhancement of synaptic transmission. Second, in agreement with previous results, buffering intracellular calcium at low concentrations blocked LTP. Third, depolarization of the postsynaptic membrane so that calcium entry is suppressed prevented LTP. Taken together, these results demonstrate that an increase in postsynaptic calcium is necessary to induce LTP and sufficient to potentiate synaptic transmission.

Long-term potentiation at nicotinic synapses in the rat superior cervical ganglion

1. Nicotinic fast excitatory postsynaptic potentials (fast EPSPs) were recorded intracellularly from postganglionic neurones in the isolated rat superior cervical ganglion. 2. An hours-long potentiation of the fast EPSP could be induced by brief tetanic stimulation of the preganglionic nerve (5 Hz for 5 s to 20 Hz for 20 s). While long-term potentiation (LTP) can be detected in every ganglion by extracellular techniques, LTP was induced in only two-thirds of the nicotinic synaptic responses. 3. Muscarinic blockade with atropine did not prevent LTP of the fast EPSP. 4. LTP of the fast EPSP did not correlate with changes in input resistance nor cell potential, as recorded in the soma. 5. The formation of nicotinic LTP appeared to depend upon stimulation of the nerve terminals. Non-synaptic tetanic depolarization of the postganglionic neurone, effected by injecting depolarizing current pulses through the intracellular microelectrode, was not sufficient. LTP could be induced by synaptic tetani in two-thirds of the same neurones. 6. The response to exogenous 1,1-dimethyl-4-phenylpiperazinium (DMPP), a selective nicotinic agonist, was not increased during nicotinic synaptic LTP. This was true whether DMPP was applied by pressure-ejection from an extracellular micropipette during intracellular recording, or by brief superfusion during sucrose-gap recording of postganglionic responses. 7. Responses to exogenous acetylcholine and carbachol were increased during nicotinic LTP when these non-selective cholinergic agonists were applied by pressure-ejection during intracellular recording. However, the potentiation of the fast EPSP was always at least twofold greater than the potentiation of the response to these exogenous agonists. 8. Potentiation of the responses to acetylcholine and carbachol may have been due to long-term enhancement of muscarinic responses. Thus, no postsynaptic basis for nicotinic LTP was uncovered in these studies.

The NMDA receptor: central role in pain inhibition in rat periaqueductal gray

An injection of the excitatory amino acid analogue, N-methyl-D-aspartate (NMDA), in the rat periaqueductal gray resulted in potent analgesia. A prior injection of the NMDA antagonist, (-)-2-amino-7-phosphonoheptanoate (D-AP7), antagonized this action, indicating a receptor-mediated action. NMDA given with morphine potentiated the morphine analgesia while D-AP7 blocked morphine analgesia. These results delineate for the first time a functional role for the NMDA receptor in the control of pain in the mammalian central nervous system.

Stimulation of NMDA receptors induces proteolysis of spectrin in hippocampus

Stimulation of N-methyl-D-aspartate (NMDA) receptors was found to induce proteolysis of brain spectrin in hippocampal slices. The effect was dependent upon extracellular calcium, blocked by the antagonist 2-amino-5-phosphonovalerate (AP5), and was not reproduced by potassium-induced depolarization. These results are consistent with the hypothesis that the involvement of NMDA receptors in plasticity and excitotoxicity is at least partially mediated by calcium-activated proteolysis of cytoskeletal proteins.

Release of proteins during long-term potentiation in the hippocampus of the anaesthetized rat

Using a push-pull device, the release of endogenous proteins in the extracellular space was investigated in the CA1 region of the hippocampus of anaesthetized rats. With low-frequency stimulation of the Schaffer collaterals, there was a relatively stable release of 5 proteins (64, 54, 48, 45 and 16 kDa). A train of high-frequency stimulation produced a long-lasting enhancement of the negative field EPSP and a delayed (90-120 min) enhancement of the release of these proteins. An additional 19 kDa protein was present only 90 min after the train. These observations raise the possibility that release of proteins might be involved in the maintenance of LTP.

Lesions of entorhinal cortex produce a calpain-mediated degradation of brain spectrin in dentate gyrus. II. Anatomical studies

Lesions of the various afferents to the hippocampus have been widely used to investigate the mechanisms underlying growth and degeneration in adult mammalian CNS. It has been proposed that disturbances in intracellular calcium and activation of calcium-dependent proteases represent key steps in producing come of the consequences of the lesions. In this study, we show that lesions of the entorhinal cortex or of the commissural pathway result in profound changes in the distribution of brain spectrin. At 2 days after lesions of the entorhinal cortex, immunoreactivity to spectrin is markedly increased in the outer molecular layer (OML) of the dentate gyrus; conversely at 2 days after commissural lesions, immunoreactivity to the same antigen is increased in the inner molecular layer. The increase in immunoreactivity to spectrin varies with survival time after lesions of the entorhinal cortex. By 24 h post lesion, the increase is homogeneous across the OML, and becomes more intense by 48 h. Between 1 and 3 weeks the increase is much less than at 48 h and is concentrated at the inner border of the OML. Pretreatment of the animals with the calpain inhibitor leupeptin reduces the increase in spectrin immunoreactivity normally seen 48 h after the lesion of the entorhinal cortex. Changes in the pattern of immunoreactivity to GFAP are very different to that seen with spectrin antibodies and are consistent with the known modifications in astrocytes that follow lesions of hippocampal afferents.(ABSTRACT TRUNCATED AT 250 WORDS)

Age-dependent alterations in hippocampal synaptic plasticity: relation to memory disorders

In this paper, we review the evidence indicating that the common disturbance in recent memory associated with aging is a consequence of functional and structural impairment in the hippocampal formation. In the Fischer 344 rat, an experimental model of the human age-related memory disorder was developed. The majority of aged rats of this strain show impaired performance in the 8-arm radial maze in a manner typical of young rats with bilateral hippocampal lesions. Aged animals also exhibit rapid decay of LTP and slower kindling of the perforant path-dentate synapse. Furthermore, quantitative morphometric analysis of the hippocampal synaptic architecture revealed that aged, memory-impaired rats had a specific loss of perforated axospinous synapses in the middle third of the dentate gyrus molecular layer; the extent of loss was directly related to the degree of memory dysfunction. Most important was the fact that the electrophysiological and morphological abnormalities did not appear in equally old animals with good memory.

Long-term potentiation: persisting problems and recent results

In this paper we discuss recent experimental results pertinent to three unresolved issues regarding the long-term potentiation (LTP) effect: the nature of its enduring substrates, the biochemical mechanisms that produce it, and its potential role in memory. LTP appears to be triggered by a postsynaptic influx of calcium and is associated with alterations in the shape of dendritic spines and probably the formation of new synapses. We discuss the possibility that morphological reorganization also modifies membrane surface chemistry of synaptic elements. Evidence is presented that LTP is not associated with changes in presynaptic calcium currents. Activation of protein kinase C is shown to be insufficient for the induction of LTP, although it may play a modulatory role. The hypothesis that activation of a calcium-sensitive protease (calpain) is pivotal to the establishment of LTP is supported by experiments showing that a calpain inhibitor, leupeptin, blocks LTP. Furthermore, activation of NMDA receptors, an event implicated in LTP induction, is accompanied by calcium-sensitive proteolysis of spectrin, a major dendritic cytoskeletal protein. The finding that stimulation patterns designed to mimic naturally-occurring cell discharge patterns are highly effective for LTP induction greatly strengthens the hypothesis that LTP actually occurs during the encoding of information in cortical systems. Potential contributions of LTP to learning are explored using computer simulations of a simple cortical network.

Measurement of intracellular Ca2+ in cerebellar Purkinje neurons in culture: resting distribution and response to glutamate

Ca ion levels in cerebellar Purkinje neurons, in culture, have been measured using the fluorescent indicator, fura-2, and digital imaging. Cells were loaded with the indicator both by injecting the free acid form and by allowing the membrane permeant form (/AM) become deesterified and trapped. The two methods gave significantly different results in that the /AM loaded cells showed localized regions of high Ca2+ in the soma whereas the injected cells did not. Resting levels in the remainder of the cytoplasm were similar however, as were the excursions in Ca2+ induced by electrical or chemical stimulation. Comparison of the data from the two methods suggests that qualitative measures of Ca in intracellular stores can be derived from the /AM loading method. Injected cells showed high Ca2+ levels in the soma that persisted for 3-8 minutes following removal of the injection electrode. The dendrites of these cells however maintained low Ca2+ levels and differences of several hundred nM in Ca2+ were maintained between the soma and initial dendrite segment, demonstrating directly the large Ca pumping capacity of the dendrites. Localized regions of high Ca2+ in dendrites could be generated by applying glutamate from a microelectrode in TTX-Krebs saline. When studied in culture media with 4.7 mM K, the Purkinje neurons showed a biomodal distribution of Ca2+ with 35 to 40% showing stable Ca2+ levels between 250 and 350 nM, and the remainder 80 to 130 nM Ca2+. Granule neurons on the same coverslips had Ca2+ level in the lower range in greater than 95% of the examples observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Hippocampal neurobiological mechanisms of age-related memory dysfunction

Studies are reviewed which indicate that hippocampal frequency potentiation (the growth of neural responses during repetitive synaptic stimulation) is impaired in aged rats, and that this impairment may be important in learning and memory deficits found in these aged animals. Intracellular recording and ultrastructural studies suggest that both hippocampal frequency potentiation and the age deficit in such potentiation are synaptic processes (probably presynaptic), and that the deficit may be due to an age-related increase in calcium influx during depolarization. The latter could in some way result from alterations in the function of a Ca-mediated inactivation of Ca current mechanism recently found in hippocampal neurons. Since major hippocampal changes occur with aging in both rodents and humans, it seems possible that these data are also relevant to human brain aging. Consequently, it is suggested that Alzheimer's disease results from an acceleration of normal age-related neuronal calcium conductance changes by some unknown process (e.g., viruses, aluminum, genetic factors, etc.), leading to a rapid deterioration of brain structure.

Effect of dihydroergotoxine mesylate (Hydergine) on delayed neuronal death in the gerbil hippocampus

The CA 1 neurons in the gerbil hippocampus exhibiting necrosis with delayed onset following 5 min ischemia were reduced markedly by the systemic administration of dihydroergotoxine mesylate (Hydergine; HYG). Immediately after 5 min of forebrain ischemia, the animals were injected intraperitoneally with HYG. Seven days after ischemia, perfusion-fixed brains were processed by conventional histology. The number of neurons per millimeter in the CA 1 pyramidal cell layer were calculated and they were labelled neuronal density. In the control group, the neuronal density was 66.03 +/- 7.37 (mean +/- SEM), in the vehicle group, it was 11.25 +/- 4.93. The neuronal density in the HYG group was 69.19 +/- 6.49. The difference in the neuronal density between the HYG group and the control group was not statistically significant. These data indicate that HYG protects on the CA 1 neurons, and this suggest that the suppression of adrenoceptors by this drugs may be the main mechanism of action. This morphologic outcome may explain the functional amelioration of mental impairment by HYG.

Isolation and structure of a pseudopeptide gamma-L-glutamyl-L-aspartic acid from Datura stramonium that impairs learning retention in mice

Datura stramonium contains a compound that impairs learning retention in mice. It has been purified to homogeneity and its structure has been established as that of a gamma-L-glutamyl-L-aspartate. The biological activity of this pseudodipeptide has been found to be identical with that of the corresponding synthetic one. It has also been compared to those of various synthetic di- and tripeptides containing L- and/or D-enantiomers of the constitutive amino acids. The results show that the activity is associated with a peptidic structure containing only one type of enantiomer.

Neurochemical characteristics of a postsynaptic density fraction isolated from adult canine hippocampus

Postsynaptic density and synaptic membrane fractions isolated from hippocampal tissue have been compared to those previously isolated from cerebellum and cerebral cortex. In all respects examined, the isolated hippocampal preparations are similar to the cerebral cortex fractions. The morphology of the postsynaptic density (PSD) preparation is the same and the protein composition is similar, but with higher concentrations of the 51-kDa major protein and of calmodulin, and lower concentrations of actin, in the hippocampal PSD fraction. The binding characteristics for glutamate and GABA are also similar between the two fractions, but with higher Bmax and KD glutamate values and lower Bmax and higher KD GABA values for the hippocampal PSD preparation. Both preparations contain GABAA and GABAB receptors. The PSD fraction contains, as does the cerebral cortex fraction, a calmodulin-dependent binding of the Ca2+ channel antagonist, nitrendipine, as well as a cAMP-dependent and a Ca2+/calmodulin-dependent protein kinase, with the same respective substrates. The value of the hippocampal fractions for studies on long-term potentiation and on kindling in the hippocampus is discussed.

Alterations in calmodulin content in fractions of rat hippocampal slices during tetanic- and calcium-induced long-term potentiation

The content of cytosolic and membrane-bound calmodulin was radioimmunologically determined in fractions of rat hippocampal slices 5 min to 7 hours after long-term potentiation (LTP) had been induced by tetanization or exposure of slices to 4 mM Ca++. In light of concepts presuming multistage dynamics in LTP development as reflecting different cellular mechanisms, similar patterns of calmodulin alterations were observed with both models: The alterations in calmodulin content occurred during the early phase(s) of LTP development and continued for two and one hours during tetanic- and calcium-induced LTP, respectively. Thus, 5-30 min after LTP elicitation, membrane-bound calmodulin increased while cytosolic calmodulin diminished and, inversely, 30 min later an increase in cytosolic and decrease in membrane-bound calmodulin were observed. Consequently, the present results indicate that calmodulin was involved in the early phases(s) of LTP development in terms of a two-step translocation sequence. Hence, calmodulin translocation within both intracellular compartments may reflect the involvement of Ca++-calmodulin-dependent intraneuronal metabolic processes which might induce and/or temporarily maintain neuronal functional changes occurring immediately after repeated or intense stimulation of synaptic functions.

Properties of quisqualate-sensitive L-[3H]glutamate binding sites in rat brain as determined by quantitative autoradiography

Quisqualate, a glutamate analogue, displaced L-[3H]glutamate binding in a biphasic manner, corresponding to "high-affinity" and "low-affinity" binding sites. High-affinity quisqualate sites were termed "quisqualate-sensitive L-[3H]glutamate" binding sites. Quisqualate-sensitive L-[3H]glutamate binding was regionally distributed, with the highest levels present in the cerebellar molecular layer. This binding was stimulated by millimolar concentrations of chloride and calcium. The stimulatory effects of calcium required the presence of chloride ions, whereas chloride's stimulatory effects did not require calcium. All of the L-[3H]glutamate binding stimulated by chloride/calcium was quisqualate sensitive and only weakly displaced by N-methyl-D-aspartate, L-aspartate, or kainate. At high concentrations (1 mM), the anion blockers 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid and 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid both reduced, by 41 and 43%, respectively, the stimulatory effects of chloride. At concentrations of 100 microM, kynurenate, L-aspartate, (RS)-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA), and L-2-amino-4-phosphonobutyric acid (L-APB) failed to displace quisqualate-sensitive L-[3H]glutamate binding in the cerebellar molecular layer. In the presence of KSCN, however, 100 microM AMPA displaced 44% of binding. Quisqualate-sensitive L-[3H]glutamate binding was not sensitive to freezing, and, in contrast to other chloride- and calcium-dependent L-[3H]glutamate binding sites that have been reported, quisqualate-sensitive binding observed by autoradiography was enhanced at 4 degrees C compared with 37 degrees C. Quisqualate-sensitive L-[3H]glutamate binding likely represents binding to the subclass of postsynaptic neuronal glutamate receptors known as quisqualate receptors, rather than binding to previously described APB receptors, chloride-driven sequestration into vesicles, or binding to astrocytic membrane binding sites.

Excitatory amino acid neurotoxicity in the hippocampal slice preparation

The effect of sustained activation of excitatory amino acid receptors on neuronal survival was studied using slices of adult rat hippocampus and light and electron microscopy. Kainate, N-methyl-D-aspartate, quisqualate, and ibotenate all produce signs of severe neurotoxicity within 90 min. Neuronal damage occurs in the form of perikaryal and dendritic swelling, cytoplasmic and nucleoplasmic disintegration, and plasma and nuclear membrane ruffling and collapse. The toxicity is restricted to intrinsic neuronal somata, dendrites and spines, while afferent axons, boutons and glia are spared. Although damage is generally distributed throughout all areas of hippocampus, kainate has little effect on pyramidal neurons in the CA2 region. Quantitative analysis of neuronal survival indicates that agonists induce dose-dependent damage over concentration ranges known to be excitatory. Based on selective antagonism by DL-aminophosphonoheptanoate and the patterns of damage produced by each, N-methyl-D-aspartate, kainate, and quisqualate trigger neurotoxicity by acting on distinct receptor classes. It is concluded that, in hippocampal slices, excitatory amino acids induce neurotoxicity in a similar manner to their actions in vivo. The results support the hypothesis that hippocampal neurotoxicity is initiated by excessive excitation, and provide another example of the capacity of adult hippocampal neurons for rapid structural modification.

Facilitation of hippocampal long-term potentiation in slices perfused with high concentrations of calcium

The effect of increased extracellular calcium on long-term potentiation (LTP) of synaptic transmission has been examined in the CA1 region of guinea pig hippocampal slice preparation using extracellular recordings from the dendritic layer. The application of high calcium (4 mM) led to an increase in the initial slope of the field potential that reversed following return to control (2 mM calcium) solution. The magnitude of the field potential change was unaffected by prior induction of LTP, and inputs tetanized after return to control solution showed the same amount of LTP as those tetanized before the high calcium application. These results suggest that the calcium application by itself did not induce LTP. Inputs tetanized in the high calcium solution showed a greater amount of potentiation than in control solution, any given train producing about twice as much potentiation. However, using long trains (40 impulses) at high strength (2 x test strength) gave similar LTP values in the two solutions. The facilitatory effect of high calcium on LTP was completely blocked by raising extracellular magnesium from 2 to 4 mM. As in control solution. LTP evoked in the high calcium solution was blocked by 2-amino-5-phosphono-valerate. The results support the view that calcium influx through postsynaptic N-methyl-D-aspartate receptor channels is directly involved in the induction of LTP.

Tissue-specific analogues of erythrocyte protein 4.1 retain functional domains

Analogues of the human erythroid membrane skeletal component protein 4.1 have been identified in perfused rat tissues and human T and B lymphocyte cell lines. olyclonal antibodies were used which are specific for all domains of protein 4.1, the spectrin-actin-promoting 8-Kd peptide, the membrane-binding 30-Kd domain, and the 50-Kd domain. Antibody reactivity, by Western blotting of tissue homogenates, shows reactivity with proteins varying in molecular weight from 175 Kd to 30 Kd. Further, these protein 4.1 analogues appear to be expressed in a tissue-specific fashion. Of the analogues detected there appear to be at least three classes: analogues containing all erythroid protein 4.1 domains, analogues containing all domains but with modified antigenic epitopes, and analogues containing only some domains. Chemical cleavage at cysteine linkages indicates that in analogues containing the 30-Kd region the location of cysteine is highly conserved. This datum suggests that in nonerythroid 4.1 isoforms of higher molecular weight the additional protein mass is added to the amino terminal end (30 Kd end).

The mechanism of ischemia-induced brain cell injury. The membrane theory

Temporal ischemia of the brain injures only the selectively vulnerable brain cells. The dying process evolves along with glutamate-mediated intracellular signal-transduction system, together with a loss of Ca2+ homeostasis. Such post-ischemic changes eventually disrupt functional and structural integrity of the cell membrane and kill the neuron. Molecular basis in pharmacoprotective agents is discussed.

Synaptic interface surface area increases with long-term potentiation in the hippocampal dentate gyrus

The present study continues our attempt to understand the ultrastructural changes that accompany and may underlie long-term potentiation (LTP). This report describes changes with LTP in the surface area of the pre- and postsynaptic membrane apposition at the synapses formed by entorhinal cortical (EC) axons with granule cell dendritic spines of the dentate gyrus (DG). The electrophysiology and electron microscopy of the DGs from each animal followed conventional procedures. The trace length of the pre- and postsynaptic apposition was measured for identified asymmetric synapses in the dentate molecular layer. The total apposed membrane surface area per unit volume (Sv) was then computed for 4 categories of synaptic profiles for each third of the molecular layer. Statistical analysis of the Sv data used multivariate analyses of variance. Across the entire molecular layer, total apposed Sv does not change significantly with LTP. However, in the activated portion of the molecular layer, total apposed Sv increases significantly, reflecting a significant increase in the apposed Sv for the concave spine profiles there. For these spine profiles, the increased apposed Sv is due to the increased membrane area both at the postsynaptic density and beyond. The average apposed surface area per individual synapse also increases markedly with LTP. The present data support the hypothesis of coordinated pre- and postsynaptic anatomical changes with LTP in the EC-DG system.

Calcium and neuronal function

Calcium is unique among metals because its ions have a very large concentration gradient across the plasma membrane of all cells, from 10(-3) M Ca2+ outside, to 10(-7) M Ca2+ inside. This gradient is maintained by the use of metabolic energy through ion pumping, and its existence allows cells to use transient increases in the intracellular Ca2+ concentration as signals, which regulate cell function. In neurones these Ca signals are initiated by electrical activity (action potentials) which open voltage-dependent Ca channels in the plasma membrane, allowing Ca to enter the cell. Intracellular Ca signals can also be produced by transmitters at synapses, which open Ca channels, either directly, or indirectly by causing local depolarization and the opening of voltage-dependent Ca channels. The main effects of Ca signals on neurones are to alter their electrical activity, by modifying the opening and closing of Na and K channels, and to stimulate the release of transmitter substance. Ca has a host of other effects, such as the regulation of metabolic activity, the regulation of cell growth, and the long-term modification of synaptic efficiency, and it is even implicated in the destruction of neurones.