Evidence for the ability of hippocampal neurons to develop acute tolerance to ethanol in behaving rats.

BACKGROUND: The cellular mechanisms underlying acute tolerance to alcohol are unclear. This study aimed to determine whether hippocampal neurons have the ability to develop acute tolerance to alcohol in behaving rats. METHODS: Intrahippocampal microdialysis was performed in freely behaving rats, and the firing of single neurons in the dialysis area was recorded. The control microdialysis fluid, artificial cerebrospinal fluid (ACSF), was replaced with 1 M ethanol in ACSF for a 30 min period. One hour later, the ethanol perfusion was repeated. To test the functional integrity of the microdialysis probe in situ, each microdialysis session was completed with recording the effect of a 10-20 min perfusion of 500 microM N-methyl-D-aspartate (NMDA). The extracellular concentration profile of ethanol during intrahippocampal microdialysis with 1 M ethanol was estimated in a separate study in anesthetized rats. The ethanol content was measured in tissue slices surrounding the probe with gas chromatography (GC), and the generated data were analyzed with a mathematical model for microdialysis to estimate the concentration of ethanol at the recording site. RESULTS: The predominant effect of the first intrahippocampal microdialysis with ethanol was a decrease in firing rate in both pyramidal cells and interneurons. In contrast, such firing rate decrease did not develop during the second ethanol perfusion. Subsequent NMDA perfusion still induced robust changes in the electrical activity of the neurons. The estimated extracellular ethanol concentration at the recording site was 45-70 mM. CONCLUSION: This study revealed that hippocampal neurons have the ability to develop acute tolerance to a single exposure of clinically relevant concentrations of ethanol in behaving rats, without influences from the rest of the body.

Single-cell recording from the brain of freely moving monkeys.

Single-cell recording from the brain of non-human primates has traditionally been performed in monkeys seated in a primate chair. However, this arrangement makes long-term recordings difficult, causes stress that may confound the data, and prevents the manifestation of natural behaviors. Extending our previous neurophysiological studies in non-human primates (Ludvig et al. Brain Res. Protocols 2000;5:75-85), we have developed a method for recording the electrical activity of single hippocampal neurons in freely moving squirrel monkeys (Saimiri sciureus). The recording sessions lasted for up to 6 h, during which the monkeys moved freely around on the walls and the floor of a large test chamber and collected food pellets. Stable action potential waveforms were readily kept throughout the sessions. The following factors proved to be critical in this study: (a) selecting squirrel monkeys for the experiments, (b) using a driveable bundle of microwires for the recordings, (c) using a special recording cable, (d) implanting the microwires into the brain without causing neurological deficits, and (e) running the recording sessions in a special test chamber. The described method allows long-term extracellular recordings from the brain of non-human primates, without the stress of chairing, during a wide range of natural behaviors. Using this model, new insights can be obtained into the unique firing repertoire of the neurons of the primate brain.

Cellular electrophysiological changes in the hippocampus of freely behaving rats during local microdialysis with epileptogenic concentration of N-methyl-D-aspartate.

N-methyl-D-aspartate (NMDA) receptor dysfunctions are thought to be involved in the pathophysiology of seizures of hippocampal origin. While the cellular effects of excessive NMDA receptor stimulation have been widely studied in vitro, no data are available on the sequence of cellular electrophysiological events that follow the overstimulation of hippocampal NMDA receptors in awake, behaving subjects. Therefore, the present study addressed this problem. Intrahippocampal microdialysis with 500 microM NMDA was performed in freely behaving rats, and the electrical activity of single neurons in the dialysis area were monitored. In all recorded neurons (n = 9), regardless of their type, NMDA induced a long-lasting electrical silence preceded in most cells by a brief but robust firing rate increase. During these firing rate increases, place cells lost the spatial selectivity of their discharges, and a gradual reduction in the amplitude of the action potentials was also observed. Remarkably, electroencephalographic (EEG) seizures developed exclusively after the appearance of cellular electrical silence in the recording/dialysis site. The NMDA-induced electrophysiological changes were reversible. This study demonstrates that the combined single-cell recording-intracerebral microdialysis technique can be readily used for inducing focal epileptiform events in the hippocampus and monitoring the induced cellular electrophysiological events in behaving animals.

Delivering drugs, via microdialysis, into the environment of extracellularly recorded hippocampal neurons in behaving primates.

Hippocampal neurons in primates have been extensively studied with electrophysiological and neuroanatomical methods. Much less effort has been devoted to examining these cells with contemporary pharmacological techniques. Therefore, we modified a recently developed integrative technique (N. Ludvig, P.E. Potter, S.E. Fox, Simultaneous single-cell recording and microdialysis within the same brain site in freely behaving rats: a novel neurobiological method, J. Neurosci. Methods 55 (1994) 31-40 [9] ) for cellular neuropharmacological studies in behaving monkeys. A driveable microelectrode-microdialysis probe guide assembly was implanted stereotaxically into the left hippocampus of squirrel monkeys (Saimiri sciureus) under isoflurane anesthesia. The assembly was covered with a protective cap. After 3 weeks of postsurgical recovery and behavioral training, the experimental subject was seated in a primate chair. For 4-5 h, single-cell recording and microdialysis were simultaneously performed in the hippocampal implantation site. The technique allowed the recording of both complex-spike cells and fast-firing neurons without the use of head restraint. The control microdialysis solution, artificial cerebrospinal fluid (ACSF), was replaced with either 1 M ethanol or 500 microM N-methyl-D-aspartate (NMDA) for 10-30 min intervals. The ethanol perfusions principally suppressed the firing of the neurons in the dialysis area. The NMDA perfusions initially increased the firing of local neurons, then caused electrical silence. These drug delivery/cell recording sessions were performed with 1-4 day intersession intervals over a 1-month period. The described method provides a tool to elaborate the pharmacology of primate hippocampal neurons during behavior and without the confounding effects of systemic drug administrations.

Place cells can flexibly terminate and develop their spatial firing. A new theory for their function.

In this study, hippocampal place cells were recorded in a behavioral paradigm previously not employed in place-cell research. Rats were exposed to the same fixed environment for as long as 8-24 h without interruption, while the firing of CA1 and CA3 place cells was monitored continuously. The first finding was that all place cells that were detected at the beginning of the recording sessions ceased to produce location-specific firing in their original firing fields within 2-12 h. This was observed despite the fact that the animals kept visiting the original firing fields, the hippocampal EEG was virtually unchanged, and the discriminated action potentials of the cells could be clearly recorded. The second finding was that some complex-spike cells that produced no spatially selective firing pattern at the beginning of the recording sessions developed location-specific discharges within 3-12 h. Thus, place cells can flexibly terminate and develop their spatial firing. even in a fixed environment and during similar behaviors, if that environment is explored continuously for a prolonged period. To explain this phenomenon, a new place-cell theory is outlined. Accordingly, the high-frequency discharges of these neurons may serve to create, under multiple extrahippocampal control and within limited periods, stable engrams for specific spatial sites in the association cortex where the cognitive map probably resides. After the creation of a stable engram, or in the absence of favorable extrahippocampal inputs, place cells may suspend their location-specific firing in the original field, and initiate the processing of another spatial site.

Application of the combined single-cell recording/intracerebral microdialysis method to alcohol research in freely behaving animals.

Intercellular communication in brain is coded in neuronal firing patterns, determined by the interplay of intra- and extracellular molecular systems. It is not clear how ethanol perturbs this molecular interplay in the motivational, emotional, and cognitive neural networks in brain to induce those specific, aberrant, cell-firing patterns that lead to craving for alcohol, excessive alcohol consumption, and impaired cognition. However, resolution of this problem is essential to an understanding of the basic mechanisms of alcohol-related disorders and to develop effective therapies for their treatment. It is difficult to obtain information on the molecular background of cell-firing regulation in brain during behavioral events. We have recently developed a new in vivo method, combined single-cell recording/intracerebral microdialysis in freely behaving animals, which has the ability to extract such information from brain. The principal feature of the technique is that it records the firing of single neurons in discrete brain sites and deliver drugs, alone or in combinations, via microdialysis, into the extracellular environment of the recorded cells, while the experimental animal is behaving freely. Accordingly, the method allows the determination of drug actions on cellular firing within distinct neural circuits during normal and abnormal behaviors. Thus, it can provide insights into the physiological or pathophysiological molecular machinery of the examined cells. The present paper describes this method, demonstrates how administration of ethanol via intrahippocampal microdialysis affects the firing of hippocampal place cells, and discusses the potential of the technique in future alcohol research.

Microdialysis-coupled place cell detection in the hippocampus: a new strategy for the search for cognition enhancer drugs.

1. The MPCD method in freely moving rats is a new neuroscience technique. It is able to detect the location-specific firing of hippocampal place cells, and to deliver, via microdialysis, various drug solutions into the extracellular environment of the detected neurons. Place cells are critical elements of the neural system in brain which governs cognitive processes. It is emphasized in this article that effective cognition enhancer drugs must selectively and significantly affect the firing of these cells. 2. By using MPCD, it is possible to recognize drug combinations which can increase the location-specific firing of place cells to an optimal level. This paper proposes that such pharmacological action facilitates engram-creation in extrahippocampal cortical areas, improving cognitive functions. Thus, an MPCD-based research strategy may lead to the rational development of a new generation of cognition enhancer drugs for the treatment of learning and memory disorders, including Alzheimer's disease (AD).

Manipulation of pyramidal cell firing in the hippocampus of freely behaving rats by local application of K+ via microdialysis.

In this study, microdialysis was performed in the hippocampus of freely behaving rats, and the firing of pyramidal cells, including place cells, was recorded at the site of the microdialysis probe. For 10-min periods, the artificial cerebrospinal fluid (ACSF) in the microdialysis system was replaced with ACSF containing 50 mM K+ (high K+ solution). Complementary in vitro tests determined that microdialysis with such high K+ solution produced an outflow of 5% of the perfused K+ from the microdialysis probe. Application of K+ with this method into the CA1 region significantly increased the firing of the local pyramidal cells, including place cells, during both movement and sleep. On average, K+ exposures increased the firing rate of the neurons to 306% and 448% of the control firing rate during movement and sleep, respectively. After the termination of the K+ outflow, the cells continued to discharge for 5-30 min with a significantly higher frequency than before the K+ challenge. This phenomenon also occurred in both behavioral states. During the period of enhanced firing, the out-of-field firing rate of the recorded place cells was dramatically increased. It was also found that during the K+ applications, otherwise silent pyramidal cells often became electrically active. The K(+)-induced firing modifications were usually not accompanied by behavioral or EEG changes. The data raise the possibility that transient elevations in the extracellular K+ concentration contribute to the ionic/molecular processes which are responsible for plastic firing pattern modifications in hippocampus. Pharmacological manipulation of place cells with the described method offers a new strategy to understand the molecular bases of spatial memory.

The suppressant effect of ethanol, delivered via intrahippocampal microdialysis, on the firing of local pyramidal cells in freely behaving rats.

Intrahippocampal microdialysis was performed on 14 freely behaving rats, and the firing of pyramidal cells within the dialysis area was recorded. In one group of rats, the microdialysis was conducted only with artificial cerebrospinal fluid (ACSF) for 2-4 h. In this control group, the recorded neurons displayed normal firing patterns. In another group, ACSF was replaced for 30-60 min with various concentrations of ethanol to deliver this drug via the microdialysis probe into the cell recording area. Ethanol at the concentration of 5% (w/v) significantly and reversibly suppressed the firing of the recorded neurons. The marked firing rate alterations were not accompanied with apparent changes in the hippocampal EEG activity or the behavior of the rats, indicating localized drug actions. These data demonstrate for the first time that in the physiologically functioning brain, ethanol exerts principally a suppressant effect on the electrical activity of hippocampal pyramidal cells.

Simultaneous single-cell recording and microdialysis within the same brain site in freely behaving rats: a novel neurobiological method.

We present a method for performing intracerebral microdialysis in freely behaving rats while recording the firing of neurons within the dialysis site. Studying hippocampal theta cells and complex-spike cells with this technique, it has been found that: (1) when the microdialysis fluid contained only artificial cerebrospinal fluid, both types of neurons displayed normal electrical activity, (2) the simultaneous single-cell recording/microdialysis procedure could be readily performed for as long as 3 days, and (3) inclusion of drugs into the microdialysis fluid, at appropriate concentrations, caused clear changes in firing pattern. For example, microdialysis with 1% lidocaine completely abolished, whereas that with 50 mM K+ markedly increased, the neuronal electrical activity. These cellular changes developed without apparent EEG or behavioral manifestations and were reversible. In some of the experiments, the extracellular concentrations of glutamate and aspartate in the recording/dialysis site were also measured. The described method allows the extracellular environment of recorded brain cells to be manipulated by drugs delivered through the microdialysis probe and simultaneously allows determination of the neurochemical composition of that environment over a remarkably long period of time and in intact, physiologically functioning, neural network. Such studies will provide new insights into the molecular basis of neuronal activity in the brain in the context of behavior, including learning.

The paradoxical effect of NMDA receptor stimulation on electrical activity of the sensorimotor cortex in freely behaving rats: analysis by combined EEG-intracerebral microdialysis.

This study was designed to determine the effects of N-methyl-D-aspartate (NMDA) receptor stimulation on the electrical activity of neocortex in freely behaving rats. Electroencephalogram (EEG) recording and intracerebral microdialysis were conducted simultaneously in the same site of the sensorimotor cortex, where the basal extracellular concentrations of aspartate and glutamate were 2.1 +/- 0.7 microM and 11.5 +/- 2.4 microM, respectively. Microdialysis with NMDA solutions (ranging from 10.0 microM to 10.0 mM) reduced the amplitude of the EEG activity and decreased the power of all frequency bands, with a virtual elimination of the high frequency waves, in a dose-dependent manner. These EEG changes were reversed after washing out the drug from the microdialysis fluid, and could be effectively antagonized with the competitive NMDA receptor antagonist DL-2-amino-5-phosphonovalerate. Remarkably, the NMDA actions were not associated with epileptiform behavioral or electrographic events. Control studies demonstrated that in the same experimental conditions, cholinergic receptor agonist carbachol caused seizures, and microdialysis with NMDA in the hippocampus readily induced epileptiform spikes. Our study shows that NMDA receptor stimulation in the rat sensorimotor cortex, although excitatory at synaptic level, can depress the local EEG activity. This may indicate that the NMDA receptor-mediated signals are processed by the neocortical network in a different way than by many other brain circuitries including hippocampus.

The combined EEG-intracerebral microdialysis technique: a new tool for neuropharmacological studies on freely behaving animals.

In this study we combined EEG and intracerebral microdialysis techniques in freely behaving rats. Various drugs were delivered into the hippocampus and cerebral cortex by means of microdialysis and, simultaneously, the EEG activity of the dialyzed area was monitored. The microdialysis procedure itself, when artificial cerebrospinal fluid was perfused, did not change the normal hippocampal or cortical EEG pattern. Drug inclusions into the microdialysis fluid, however, caused marked changes in the electrical activity of the dialyzed sites. In this report we present the following examples: (1) the dose-dependent spike-provoking effect of NMDA in hippocampus, (2) the potentiation of this NMDA effect in hippocampus by dibutyryl cyclic AMP, and (3) the EEG depressant effect of high concentration of K+ in the cerebral cortex. The artificial cerebrospinal fluid and drug solutions were alternated in the microdialysis system with a 2-way valve placed outside the test chamber. As a consequence, the drugs were delivered into the brain without interrupting the ongoing behavior, including sleep, of the examined animals. This study shows that the combined EEG-intracerebral microdialysis technique is a useful tool, with many unique advantages, for in vivo neuropharmacological studies.

Dibutyryl cyclic AMP has epileptogenic potential in the hippocampus of freely behaving rats: a combined EEG-intracerebral microdialysis study.

The effects of dibutyryl cyclic AMP were studied with the combined EEG-intracerebral microdialysis technique in the hippocampus of freely behaving rats. It was found that intrahippocampal microdialysis with this drug produced epileptiform EEG events associated with limbic type behavioral seizures. The dibutyryl cyclic AMP-induced seizures developed with a long latency, and persisted for a prolonged period even after the removal of the drug from the microdialysis fluid. Similar EEG or behavioral manifestations did not occur during intrahippocampal microdialysis with artificial cerebrospinal fluid or ATP solutions. These data suggest that in the hippocampus, in vivo, the cyclic AMP second messenger system may be involved in potentially epileptogenic excitatory processes.

Electron microscopic immunocytochemical evidence that the calmodulin-dependent cyclic nucleotide phosphodiesterase is localized predominantly at postsynaptic sites in the rat brain.

The calmodulin-dependent cyclic nucleotide phosphodiesterase represents an important junction between the Ca2+ and the cyclic AMP/cyclic GMP second messenger systems. In brain it is a major cyclic nucleotide-degrading activity and is selectively expressed in the soma and dendrites of regional output neurons [Kincaid et al. (1987) Proc. natn. Acad. Sci. U.S.A. 84, 1118-1122]. In this study the subcellular localization of this enzyme in cerebral cortex, hippocampus and inferior colliculus of rat brain was analysed by electron microscopic immunocytochemical methods using affinity-purified antibodies. The immunoreactivity was found exclusively within neurons whereas glial cells were unstained; preabsorption of antibody with phosphodiesterase eliminated this reactivity, demonstrating the specificity of immunostaining. In the neuronal cell bodies, deposits of immunoreaction product occurred as sparse patches in the cytoplasm and were often associated with organelles such as mitochondria, Golgi-complex and endoplasmic reticulum; nuclei, however, were free from immunoreaction product. In the neuronal processes immunoreactivity was found within dendrites and dendritic spines, whereas the myelinated axons and axon terminals were immunonegative. The postsynaptic densities of asymmetric synapses were associated with especially high concentrations of immunoreaction product. However, the immunopositive synaptic profiles appeared to be quite selective, comprising only a small percentage of the total number of synapses in the neuropil. Our results indicate that the calmodulin-dependent cyclic nucleotide phosphodiesterase is concentrated at postsynaptic sites in specific classes of neurons. This finding supports other morphological evidence indicating a primary role for cyclic nucleotide action in postsynaptic and not presynaptic structures. Furthermore, since this enzyme is regulated by Ca2+, this interface between second messenger systems seems to play a significant role in the postsynaptic integration of Ca(2+)-mediated neuronal inputs.

Scope and contribution of genetic models to an understanding of the epilepsies.

Studies of the genetic models of the epilepsies emphasize that some seizure disorders result from an aberrant "wiring diagram" coupled with abnormal activity of individual neurons. These defects cause the unique seizer-triggering mechanisms operative within the epileptic nervous system but which are inactive or do not exist in normal subjects. Moreover, causes of epilepsy reside not only within the brain area, wherein initial appearance of epileptic EEG discharge occurs, but also outside that region. Etiologically significant neurochemical dysfunctions may be common features of the epileptic condition in genetic models across species. Accordingly, genetically determined convulsive epileptogenesis in rats, baboons, and humans may result partially from noradrenergic and GABAergic deficits. In contrast, genetically derived absence seizures in the rat and perhaps also humans may occur in response to GABAergic excess. The unique features of the genetically epileptic animals emphasize their usefulness in developing novel drugs that selectively ameliorate seizure predisposition.

An analysis of various environmental and specific sensory stimuli on the seizure activity of the Mongolian gerbil.

Mongolian gerbils were subjected to different environmental and specific sensory stimuli to determine the ability of these stimuli to provoke seizures. None of the specific sensory stimuli, somatosensory, olfactory, auditory or visual, were effective in inducing convulsions. This finding does not implicate dysfunctions of the specific sensory pathways in seizure genesis in gerbils. In contrast, several novel environmental stimuli that exposed the animals to a difficult exploratory task (i.e., Y-maze, disk rack, etc.) could trigger seizures, and this suggests that the pathophysiology of epileptiform events in gerbils may have a unique association with exploratory behavior. However, the frequency, latency and severity of the seizures showed no correlation with each other, indicating that these parameters are probably determined by independent factors. Taken together with previous studies on the electrophysiology of the dentate gyrus during exposure to novel experiences, and the anatomical abnormalities found in the hippocampus of the seizure-sensitive gerbil, these behavioral data provide further support for a significant role of the hippocampus in the pathophysiology of seizures in this model of genetic epilepsy.

Immunocytochemical localization of the neural-specific regulatory subunit of the type II cyclic AMP-dependent protein kinase to postsynaptic structures in the rat brain.

The cellular and subcellular distribution of a major cyclic AMP binding protein in the central nervous system, the neural-specific regulatory subunit of the type II cyclic AMP-dependent protein kinase (RII-B), was analyzed in rat brains with light and electron microscopic immunocytochemical methods. The distribution of the non-neural isoform of the regulatory subunit of the enzyme (RII-H) was also analyzed. It was found that RII-B immunoreactivity was predominantly localized to neurons whereas glial and endothelial cells were unlabeled. In the neurons the RII-B immunoreactivity occurred in the perikaryal cytoplasm and in the dendrites; there was no significant accumulation of immunoreaction product in nuclei, myelinated axons and axon terminals. Although immunoreactivity was never detected in axon terminals, it was characteristically associated with the postsynaptic densities and the surrounding non-synaptic sites in somata, dendrites and dendritic spines. The localization of RII-B antigenic sites did not show specificity to any type of neuron or synapse, but the amount of immunoreactivity varied. The distribution of RII-H immunoreactivity was similar to that of RII-B except that RII-H immunoreaction product was also observed in glial cells and occurred more frequently in myelinated axons. Our data confirm that RII-B is one of the major cyclic AMP binding proteins in neurons, and provide morphological support for the involvement of the type II cyclic AMP-dependent protein kinase in postsynaptic neural functions.