Soluble beta-amyloid induces Alzheimer's disease features in human fibroblasts and in neuronal tissues

It has been shown that K+ channels, Cp20 (a 20kD GTP-binding protein), and intracellular calcium release, play a key role in associative memory storage. These same elements have been shown to be altered in fibroblasts from Alzheimer's Disease (AD) patients. In addition, it has been shown that PKC, also implicated in memory storage and closely related to the above mentioned components, is also altered in AD fibroblasts. Moreover, beta-amyloid was capable of inducing an AD-like phenotype for K+ channels and Cp20 in otherwise normal fibroblasts, providing additional evidence for the potential involvement of these components in AD and suggesting a possible pathological consequence of soluble beta-amyloid elevation in AD. Preliminary evidence shows that comparable changes in potassium channel function are also present in human olfactory neuroblasts from AD patients. These results indicate that the observed changes not only occur in peripheral tissues such as fibroblasts, but also in neural tissue, the primary site of AD pathology.

Orange juice classification with a biologically based neural network

Dystal, an artificial neural network, was used to classify orange juice products. Nine varieties of oranges collected from six geographical regions were processed into single-strength, reconstituted or frozen concentrated orange juice. The data set represented 240 authentic and 173 adulterated samples of juices; 16 variables [8 flavone and flavanone glycoside concentrations measured by high-performance liquid chromatography (HPLC) and 8 trace element concentrations measured by inductively coupled plasma spectroscopy] were selected to characterize each juice and were used as input to Dystal. Dystal correctly classified 89.8% of the juices as authentic or adulterated. Classification performance increased monotonically as the percentage of pulpwash in the sample increased. Dystal correctly identified 92.5% of the juices by variety (Valencia vs non-Valencia).

Pairing-specific long-term depression of Purkinje cell excitatory postsynaptic potentials results from a classical conditioning procedure in the rabbit cerebellar slice

1. Using a rabbit cerebellar slice preparation, we stimulated a classical conditioning procedure by stimulating parallel fiber inputs to Purkinje cells with the use of a brief, high-frequency train of eight constant-current pulses 80 ms before climbing fiber inputs to the same Purkinje cell were stimulated with the use of a brief, lower frequency train of three constant-current pulses. In all experiments, we assessed the effects of stimulation by measuring the peak amplitude of Purkinje cell excitatory postsynaptic potentials (EPSPs) to single parallel fiber test pulses. 2. Intradendritically recorded Purkinje cell EPSPs underwent a long-term (> 20 min) reduction in peak amplitude (30%) after paired stimulation of the parallel and climbing fibers but not after unpaired or parallel fiber alone stimulation. We call this phenomenon pairing-specific long-term depression (PSD). 3. Facilitation of the peak amplitude of a second EPSP elicited by a parallel fiber train occurred both before and after paired stimulation suggesting that the locus of depression was not presynaptic. Depression of the peak amplitude of a depolarizing response to focal application of glutamate following pairings of parallel and climbing fiber stimulation added support to a suggested postsynaptic locus of the PSD effect. 4. The application of aniracetam potentiated EPSP peak amplitude by 40%, but these values returned to baseline as a result of pairings. With the removal of aniracetam from the bath 20 min after pairings, normal levels of pairing-specific EPSP depression were observed, indicating that the effect did not result from direct desensitization of alpha-amino-3-hydroxy-5-methyl-4-isoxazole-proprionic acid (AMPA) receptors. 5. Incubation of slices in the protein kinase inhibitor H-7 potentiated EPSP peak amplitudes slightly (9%), but peak amplitudes returned to baseline levels after pairings. The net reduction in EPSP peak amplitude of < 10% after pairings suggested that H-7 partially blocked PSD and that, in turn, PSD involved protein kinases. 6. The means of induction and the specificity of those means suggest that the phenomenology of PSD is fundamentally different from that of long-term depression. PSD only occurs with pairings of trains of parallel fiber and climbing fiber stimulation; it occurs without the need for bicuculline; and it can overcome the blocking effects of aniracetam. 7. Nevertheless, the involvement of protein kinases and the potential role of calcium suggest that the mechanisms involved in the induction of PSD and long-term depression have a number of features in common. 8. Because of the pairing-specific nature of the long-term synaptic depression observed in these experiments, PSD provides a mechanism that may contribute to the role of the cerebellar cortex in classical conditioning.

Phosphorylation of the conditioning-associated GTP-binding protein cp20 by protein kinase C

The phosphorylation state of cp20, a low molecular weight membrane-associated GTP-binding protein, was previously shown to increase two- to threefold 24 h after associative conditioning. Here, cp20 is shown to be phosphorylated by protein kinase C (PKC) in vitro. Pronounced differences in activity were observed with the three major isoforms of PKC, whereas casein kinase, calcium/calmodulin-dependent protein kinase II, and cyclic AMP-dependent protein kinase produced no detectable phosphorylation of cp20. Phosphorylation of cp20 had no effect on its GTPase or GTP-binding activity but caused a translocation of cp20 from cytosol to the nuclei/mitochondrial particulate fraction. These results suggest that the increase in phosphorylation of cp20 after conditioning may be due to PKC.

Long-term synaptic transformation of hippocampal CA1 gamma-aminobutyric acid synapses and the effect of anandamide

Evidence is presented for a distinctive type of hippocampal synaptic modification [previously described for a molluscan gamma-aminobutyric acid (GABA) synapse after paired pre- and postsynaptic excitation]: transformation of GABA-mediated synaptic inhibition into synaptic excitation. This transformation persists with no further paired stimulation for 60 min or longer and is termed long-term transformation. Long-term transformation is shown to contribute to pairing-induced long-term potentiation but not to long-term potentiation induced by presynaptic stimulation alone. Further support for such mechanistic divergence is provided by pharmacologic effects on long-term transformation as well as these two forms of long-term potentiation by Cl- channel blockers, glutamate and GABA antagonists, as well as the endogenous cannabinoid ligand anandamide.

Transforming growth factor beta induces a beta-responsive calcium fluxes in neurons

The beta-amyloid (a beta) peptide is a neurotoxic peptide that accumulates in the brains of Alzheimer patients, but is also present in body fluids at subnanomolar levels. The potential effects of these low levels of a beta are unclear. We have recently shown that physiologic levels of a beta increase tyrosine phosphorylation and induce increases in cytosolic calcium. The basement membrane mixture, Matrigel, is required for observation of the a beta-induced calcium response. We now show that transforming growth factor beta (TGF beta) is the active component in Matrigel eliciting the a beta/calcium response. The response to the type of TGF beta varies depending on the cell type with TGF beta 1 eliciting a beta responsiveness in olfactory neuroblasts, and TGF beta 2 eliciting a beta responsiveness in PC12 cells.

Conditioning-specific modification of the rabbit's unconditioned nictitating membrane response

Robust classical conditioning modifies responding to the unconditioned stimulus (US) in the absence of the conditioned stimulus (CS), a phenomenon the researchers called conditioning-specific reflex modification. Unconditioned responses (URs) to periorbital stimulation varying in intensity and duration were assessed before and after 1, 3, or 6 days of paired, explicitly unpaired, or no presentations of tone and electrical stimulation. After 3 days of pairings, conditioned responding (CRs) reached 94%, and there was an increase in latency to the peak of URs. The peak latency increase was replicated in a second experiment where rabbits reached asymptotic conditioning during 6 days of pairings. There was also a conditioning-specific increase in the amplitude of URs. There were no UR changes as a function of low level of CRs following 1 day of pairings. Data suggest that there are learning-specific changes in pathways mediating the US/UR, as well as in those mediating the CS/CR.

Physiological levels of beta-amyloid increase tyrosine phosphorylation and cytosolic calcium

The a beta peptide is a neurotoxic peptide that accumulates in the brains of Alzheimer patients, but is also present in body fluids at subnanomolar levels. The potential effects of these low levels of a beta are unclear. We now show that one such action is to increase tyrosine phosphorylation in PC12 cells and olfactory neuroblasts. Application of a beta 25-35 or a beta 1-40 induces a dose-dependent increase in the tyrosine phosphorylation in both whole cells and in vitro. The increase in tyrosine phosphorylation is both rapid and sensitive, being stimulated by picomolar doses of a beta and occurring within 1 min of application. Calcium imaging experiments provide further support for the role of tyrosine phosphorylation in the action of a beta. While a beta does not alter calcium metabolism under basal conditions, the addition of a beta induces a rapid increase in cytoplasmic calcium in olfactory neuroblasts that have been treated with the tyrosine phosphatase inhibitor, sodium orthovanadate or in PC12 cells treated with nerve growth factor. These responses could be blocked by the tyrosine kinase inhibitor, herbimycin. These calcium responses displayed an obligate requirement for the presence of matrix proteins. The identification of a rapid, sensitive assay for the action of a beta may facilitate investigations of its mechanism of action.

Protein kinase C in the hippocampus is altered by spatial but not cued discriminations: a component task analysis

The exact role of the mammalian hippocampus in memory formation remains essentially as an unanswered question for cognitive neuroscience. Experiments with humans and with animals indicate that some types of mnemonic associative processes involve hippocampal function while others do not. Support for the spatial processing hypothesis of hippocampal function has stemmed from the impaired performance of rats with hippocampal lesions in tasks that require spatial discriminations, but not cued discriminations. Previous procedures, however, have confounded the interpretation of spatial versus cued discrimination learning with the number and kinds of irrelevant stimuli present in the discrimination. An empirical set of data describing a role of protein kinase C (PKC) in different mnemonic processes is similarly being developed. Recent work has implicated the activation of this serine-threonine kinase in a variety of learning paradigms, as well as long-term potentiation (LTP), a model system for synaptic plasticity which may subserve some types of learning. The present study employs the principles of component task analysis to examine the role of membrane-associated PKC (mPKC) in hippocampal-dependent memory when all factors other than the type of learning were equivalent. The results indicate that hippocampal mPKC is altered by performance in hippocampally-dependent spatial discriminations, but not hippocampally-independent cued discriminations and provide a general experimental procedure to relate neural changes to specific behavioral changes.

Alzheimer and beta-amyloid-treated fibroblasts demonstrate a decrease in a memory-associated GTP-binding protein, Cp20

The two proteins most consistently identified in the brains of patients with Alzheimer disease (AD) have been beta-amyloid and tau, whose roles in the physiology or pathophysiology of brain cells are not fully understood. To identify other protein(s) involved in AD that have been implicated in physiological contexts, we undertook to analyze a specific memory-associated protein, Cp20, in fibroblasts from AD and control donors. Cp20, a GTP-binding protein that is a member of the ADP-ribosylation factor family, was significantly decreased in fibroblasts from AD patients. Normal control fibroblasts exposed to 10 nM beta-amyloid, the same concentration that induced AD-like K+ changes in control fibroblasts, showed a similar decrease in Cp20. Since it has been previously demonstrated that Cp20 is a potent regulator of K+ channels, these findings suggest that changes in this memory-associated protein may explain previously observed differences in AD K+ channels and suggest a pathophysiologic involvement linked to soluble beta-amyloid metabolism that could contribute to the characteristic memory loss of AD.

Conditioning-specific modification of the rabbit's unconditioned nictitating membrane response

Robust classical conditioning modifies responding to the unconditioned stimulus (US) in the absence of the conditioned stimulus (CS), a phenomenon the researchers called conditioning-specific reflex modification. Unconditioned responses (URs) to periorbital stimulation varying in intensity and duration were assessed before and after 1, 3, or 6 days of paired, explicitly unpaired, or no presentations of tone and electrical stimulation. After 3 days of pairings, conditioned responding (CRs) reached 94%, and there was an increase in latency to the peak of URs. The peak latency increase was replicated in a second experiment where rabbits reached asymptotic conditioning during 6 days of pairings. There was also a conditioning-specific increase in the amplitude of URs. There were no UR changes as a function of low level of CRs following 1 day of pairings. Data suggest that there are learning-specific changes in pathways mediating the US/UR, as well as in those mediating the CS/CR.

Molecular mechanisms of associative memory and their clinical implications

In order to study how the human brain acquires, records, and recalls the relationships that comprise the images of human memory, our laboratory initiated a research strategy more than two decades ago. The strategy began with the hypothesis that the complex patterns of human memory are constructed from numerous simple relationships that are distributed over sensory space in our experience. This hypothesis further proposed that repeatable fundamental network architectures are distributed over brain structures to create internal images of our external and internal sensory experience. Based on this hypothesis, the first element of our research strategy was to (1) identify fundamental network architectures that learn and remember simple associative relationships such as those of Pavlovian conditioned responses; (2) demonstrate that the network biophysical and biochemical mechanisms of associative learning and memory in fundamental network architectures are conserved across species as diverse as those of snails, rabbits, and other mammals; (3) demonstrate that conserved memory mechanisms are targets of pathologic involvement in a human disease characterized by memory loss such as early Alzheimer's disease; (4) and derive mathematical and logical descriptions of the functions of biological associative network architectures during learning and memory. These descriptions would then be used to design artificial neural networks that would be implemented within computer programs. Observations demonstrating the plausibility of this research strategy are presented and discussed.

Molecular mechanisms of memory and the pathophysiology of Alzheimer's disease

Research on molecular and biophysical mechanisms of associative learning and memory storage identified a number of key elements that are phylogenetically conserved. In both vertebrates and invertebrates, K+ channels, PKC, Cp20, and intracellular Ca2+ regulation play a fundamental role in memory mechanisms. Because memory loss is the hallmark and perhaps the earliest sign of Alzheimer's disease, we hypothesized that these normal memory mechanisms might be altered in AD. With the use of a variety of experimental methodologies, our results revealed that one of the critical elements in memory storage, K+ channels, are dysfunctional in AD fibroblasts. Moreover, beta-amyloid induced the same K+ dysfunction in normal cells. Intracellular Ca2+ release, also associated with molecular memory mechanisms, was found altered in fibroblasts from patients with AD. The results therefore strongly suggest that biophysical and molecular mechanisms of associative learning could be altered in AD and that they may contribute to the memory loss observed early in the disease.

Incorporation of fluorescent lipids into living rabbit hippocampal and cerebellar slices

Incorporation of exogenously applied fluorescent lipids into living cells was exploited to probe cellular structure and function in living hippocampal and cerebellar slices as assessed by fluorescent imaging techniques and intracellular recording. Nitrobenzoxadiole-phosphatidylcholine (NBD-PC) and BODIPY phorbol ester, in vitro substrates of phospholipase activity and protein kinase C, respectively, were incorporated and distributed into specific cell populations. In the hippocampal slice, both probes labeled the somata and proximal dendrites of pyramidal and granule cells but were hetrogeneously distributed across the different hippocampal fields. Changes in fluorescent properties of NBD-PC in individual pyramidal cell and granule cell somata were quantified upon challenge with a muscarinic agonist known to modulate phospholipase A2 activity. In the cerebellar slice, both probes labeled Purkinje cell bodies and dendrites but only NBD-PC labeled stellate and granule cells. The cellular and functional specificity of these fluorescent lipid probes shows great promise for monitoring biochemical events in complex neuronal systems with significant spatial and temporal resolution.

Characterization of a GTP-binding protein implicated in both memory storage and interorganelle vesicle transport

The phosphorylation state of cp20, a low molecular weight GTP-binding protein that is a high-affinity substrate for protein kinase C, was previously shown to change after associative conditioning of molluscs and mammals and to induce many of the biophysical and structural modifications that accompany memory retention. Here, cp20 was purified from squid optic lobes and biochemically characterized. A monoclonal antibody prepared against squid cp20 reacted with Hermissenda cp20 and a 20-kDa protein in rabbit hippocampus, while a polyclonal antibody also cross-reacted with Sar1p and ADP-ribosylation factor (ARF). A partial peptide sequence of squid cp20 was 50% identical (23/46 amino acids) with Sar1p, a yeast GTP-binding protein involved in vesicle transport, indicating that cp20 is probably a new member of the ARF family. This classification is consistent with our recent demonstration that cp20 affects retrograde movement of intraaxonal organelles or particles and suggests a possible role for particle traffic between intraneuronal organelles in memory acquisition.

Induction of photoresponse by the hydrolysis of polyphosphoinositides in the Hermissenda type B photoreceptor

Direct evidence that the photoresponse of the Hermissenda type B photoreceptor cell is triggered directly by the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2) was obtained. Neomycin and spermine, which inhibit PIP2 breakdown, suppressed light response, while injection of inositol 1,4,5-trisphosphate (IP3), guanosine 5'-(3-O-thio)triphosphate (GTP gamma S), guanosine 5'-(2-O-thio)diphosphate (GDP beta S), cAMP, cGMP did not alter the light-induced Na+ influx underlying the photoresponse. Suppression of the photoresponse was also observed with decrease of total amount of membraneous PIP2 induced by injection of the phosphoinositides (PI) turnover inhibitors, isobutylmethylxanthine (IBMX), LiCl and R 59022.

Arachidonic acid and diacylglycerol ACT synergistically through protein kinase C to persistently enhance synaptic transmission in the hippocampus

In model membranes, arachidonic acid and diacylglycerol have been proposed to synergistically induce a membrane-inserted, constitutively active form of protein kinase C. We have investigated the effects of these lipid protein kinase C activators on synaptic efficacy in the Schaffer collateral input to CA1 hippocampal pyramidal cells. Arachidonic acid (5 microM) perfusion combined with repetitive afferent stimulation had no consistent effect on field excitatory postsynaptic potentials recorded in stratum radiatum, while treatment with a cell-permeable diglyceride, oleoyl-acetylglycerol (5 micrograms/ml), followed by stimulation, led to a short-term potentiation. By contrast, the combination of oleoyl-acetylglycerol and arachidonic acid gave rise to a long-lasting non-decremental potentiation of field excitatory postsynaptic potentials. The induction of potentiation was "activity dependent", as there was either no significant effect or there was a measurable depression when repetitive synaptic stimulation was omitted. Furthermore, consistent with a protein kinase C-dependent process, the potentiation was blocked by the kinase inhibitors H-7 and staurosporine. The results suggest that relatively low concentrations of arachidonic acid and diacylglycerol work synergistically through protein kinase C to persistently enhance synaptic transmission. This synergy has the makings of an associative (Hebbian) device for long-term potentiation induction operating at the second messenger level.

Soluble beta-amyloid induction of Alzheimer's phenotype for human fibroblast K+ channels

Although beta-amyloid is the main constituent of neurite plaques and may play a role in the pathophysiology of Alzheimer's disease, mechanisms by which soluble beta-amyloid might produce early symptoms such as memory loss before diffuse plaque deposition have not been implicated. Treatment of fibroblasts with beta-amyloid (10 nM) induced the same potassium channel dysfunction previously shown to occur specifically in fibroblasts from patients with Alzheimer's disease--namely, the absence of a 113-picosiemen potassium channel. A tetraethylammonium-induced increase of intracellular concentrations of calcium, [Ca2+]i, a response that depends on functional 113-picosiemen potassium channels, was also eliminated or markedly reduced by 10 nM beta-amyloid. Increased [Ca2+]i induced by high concentrations of extracellular potassium and 166-picosiemen potassium channels were unaffected by 10 nM beta-amyloid. In Alzheimer's disease, then, beta-amyloid might alter potassium channels and thus impair neuronal function to produce symptoms such as memory loss by a means other than plaque formation.

Intracellular calcium signals are enhanced for days after Pavlovian conditioning

Previous observations have implicated GABA as a neurotransmitter released by the vestibular sensory neurons ("hair cells") of the snail Hermissenda onto visual sensory neurons, the type B cells, whose cell bodies are the sites of biophysical and biochemical changes during and following Pavlovian conditioning. Still other observations demonstrated that light-GABA pairings that simulate stimuli presented during Pavlovian conditioning cause prolonged elevation of intracellular Ca2+ and transformation of GABA-induced synaptic inhibition into excitation. Intracellular Ca2+ signals in response to GABA perfused onto the postsynaptic type B terminal branches are shown here to be prolonged on days after conditioning, but not after control paradigms. These and past results demonstrate two separate sites, i.e., the cell body and the terminal branches, for learning-induced changes after Pavlovian conditioning.

Lateralization of membrane-associated protein kinase C in rat piriform cortex: specific to operant training cues in the olfactory modality

Rats were trained on an olfactory and a control modality (auditory or visual) discrimination task and brain membrane-associated protein kinase C (mPKC) was subsequently assessed using quantitative autoradiography of radiolabelled phorbol ester binding. In rats which received olfactory-cued training, mPKC showed a highly significant lateralization in the piriform cortex but not in the hippocampus. Both olfactory-trained rats and control modality rats showed a significant increase in mPKC in the hippocampus when compared to naive rats. Thus, while behavioral training procedures appeared to result in a hippocampal increase in the activated state of this enzyme as has been reported elsewhere, only olfactory learning produced an piriform cortex lateralization in the activated state of the enzyme. While the functional significance of such a change in the distribution of protein kinase C is still unclear, it does suggest that the monitoring of this enzyme's activational state may prove to be a useful tool in the study of memory formation in a wide variety of behavioral contexts.

The role of calcium in prolonged modification of a GABAergic synapse

Caudal hair cell impulses cause postsynaptic inhibition of ipsilateral type B photoreceptors in the snail Hermissenda. This inhibition is shown to be GABAergic according to a number of criteria. HPLC, mass spectrophotometric, and immunocytochemical techniques demonstrated the presence of GABA in the hair cells and their axons. GABA agonists and antagonists mimic and block the synaptic effect in a manner consistent with endogenous GABAergic transmission. Other properties, including I-V relations, conductance changes and reversal potentials, are comparable for exogenous GABA responses and endogenous effects of the hair cell impulses. This inhibitory synapse has been found to undergo a long-lasting transformation into an excitatory synapse if GABA release is paired with post-synaptic depolarization. GABA, via GABAA and GABAB receptors in the B cell, causes the opening of calcium sensitive chloride and potassium channels that leads to the post-synaptic hyperpolarization. GABA also induces a long-lasting intracellular calcium elevation at the terminal branches of the B cell that greatly outlasts the voltage responses. Synaptic transformation induced by pairings is caused by a decrease in both GABA induced chloride and potassium conductances in the post-synaptic B cell, as well as a significant prolongation of the intracellular calcium accumulation in the B cell's terminal axonal branches.

Internal Ca2+ mobilization is altered in fibroblasts from patients with Alzheimer disease

The recent demonstration of K+ channel dysfunction in fibroblasts from Alzheimer disease (AD) patients and past observations of Ca(2+)-mediated K+ channel modulation during memory storage suggested that AD, which is characterized by memory loss and other cognitive deficits, might also involve dysfunction of intracellular Ca2+ mobilization. Bombesin-induced Ca2+ release, which is inositol trisphosphate-mediated, is shown here to be greatly enhanced in AD fibroblasts compared with fibroblasts from control groups. Bradykinin, another activator of phospholipase C, elicits similar enhancement of Ca2+ signaling in AD fibroblasts. By contrast, thapsigargin, an agent that releases Ca2+ by direct action on the endoplasmic reticulum, produced no differences in Ca2+ increase between AD and control fibroblasts. Depolarization-induced Ca2+ influx data previously demonstrated the absence of between-group differences of Ca2+ pumping and/or buffering. There was no correlation between the number of passages in tissue culture and the observed Ca2+ responses. Furthermore, cells of all groups were seeded and analyzed at the same densities. Radioligand binding experiments indicated that the number and affinity of bombesin receptors cannot explain the observed differences. These and previous observations suggest that the differences in bombesin and bradykinin responses in fibroblasts and perhaps other cell types are likely to be due to alteration of inositol trisphosphate-mediated release of intracellular Ca2+.

Rabbit cerebellar slice analysis of long-term depression and its role in classical conditioning

Cerebellar long-term depression (LTD) has been proposed as a mechanism underlying classical conditioning of the rabbit nictitating membrane/eyelid response (NMR). However, LTD has only been obtained reliably when (1) cerebellar slices are bathed in GABA antagonists which abolish disynaptic inhibitory post synaptic potentials, and (2) the temporal sequence of stimulation used in slice or intact preparations is the opposite of that used in classical conditioning. Based on intradendritic Purkinje cell recordings obtained from rabbit cerebellar slices, we report that stimulation of climbing fibers and then parallel fibers in the presence of the GABA antagonist, bicuculline, produced significant depression of parallel fiber excitatory post synaptic potential (epsp) amplitude that continued to increase for at least 20 min after stimulation. However, application of the same stimulation protocol without GABA antagonists produced a brief depression of parallel fiber epsps that disappeared within minutes. Activation of parallel fibers and then climbing fibers in an order opposite to the LTD-producing sequence (i.e. a classical conditioning-like order) produced a brief depression that dissipated quickly. Stimulation of parallel fibers alone produced a small, slowly developing potentiation, but stimulation of parallel fibers during depolarization-induced local dendritic calcium spikes produced significant depression almost immediately which then declined slowly to more modest levels. Finally, stimulation of parallel fibers at frequencies used in in vivo parallel fiber-climbing fiber stimulation experiments (e.g. 100 Hz) produced an immediate and profound long-lasting epsp depression. The depression occurred, however, whether parallel and climbing fibers were stimulated separately (unpaired) or in a classical conditioning-like protocol (paired) where parallel fiber stimulation coterminated with climbing fiber stimulation (10 Hz).(ABSTRACT TRUNCATED AT 250 WORDS)