Electrophysiological correlates of presynaptic opiate receptor activation: reduction in norepinephrine-mediated inhibition from the locus coeruleus

Inhibitory responses of rat cerebellar Purkinje cells to locus coeruleus (LC) stimulation and iontophoresis of norepinephrine (NE) were examined before and after administration of morphine to determine whether the inhibitory modulation of NE release by opiates results in a functional impairment in noradrenergic synaptic action. Administration of morphine systemically (0.2-1.2 mg/kg, i.v.) or by iontophoresis reduced inhibitions in Purkinje firing elicited by LC stimulation without affecting depressions in activity induced by postsynaptic applications of NE. This antagonistic effect of morphine on LC-induced inhibition was reversed or prevented by naloxone and mimicked by administration of levorphanol but not dextrorphan. Morphine increased the excitatory response of Purkinje cells to monosynaptic input from the parallel fibers, whereas it blocked gamma-aminobutyric acid-induced inhibitions in firing via a non-opiate receptor-mediated mechanism. These results demonstrate that morphine interferes with synaptic inhibition derived from the LC and suggest that this may occur via activation of presynaptic opiate receptors residing on noradrenergic nerve terminals.     

Age-dependent changes in projections from locus coeruleus to hippocampus dentate gyrus and frontal cortex

Age-dependent changes in noradrenergic innervations of the hippocampal dentate gyrus (DG) and the frontal cortex (FC) have been studied in male F344 rats. The projections from the nucleus locus coeruleus (LC) to DG or FC with advancing age (from 7 to 27 months) in rats have been quantified by electrophysiological and immunohistochemical methods. In the electrophysiological study, we observed that the percentage of LC neurons activated antidromically by electrical stimulation (P-index) of DG or FC decreased with age. We found that the percentage of LC neurons showing multiple antidromic latencies (M-index), which suggests axonal branching of individual LC neurons, increased markedly between 15 and 17 months in DG or FC. In DG, the M-index increased steadily between 15 and 24 months. In contrast, the increased M-index in FC was maintained until 24 months. The increased M-index in both targets declined at 27 months. These results suggest that LC neurons give rise to axonal branching following the loss of projections to DG or FC with age. In the immunohistochemical study, the density of dopamine-beta-hydroxylase-positive axonal varicosities was measured in molecular, granule cell and polymorphic layers of DG. The density in the polymorphic layer significantly decreased in the earlier stage of ageing (7-19 months), whilst the density in the molecular and granule cell layers decreased in the later stage (27 months). These findings suggested that a layer-specific decline occurred with age in the noradrenergic axon terminals in DG.     

Electrophysiological evidence for locus coeruleus norepinephrine autoreceptor subsensitivity following subchronic administration of D-amphetamine

The effect produced by subchronic administration of D-amphetamine (D-AMP) on the sensitivity of norepinephrine (NE) autoreceptors in the rat locus coeruleus (LC) was studied by means of single unit recording and microiontophoretic techniques. Twice daily i.p. administration of 5 mg/kg D-AMP for one week markedly reduced the ability of i.v. D-AMP and microiontophoretic application of clonidine to suppress the firing of LC NE neurons, suggesting strongly that NE autoreceptors became subsensitive. In addition, the firing pattern of NE neurons became 'disorganized' following subchronic AMP treatment.     

Electrophysiological evidence for locus coeruleus norepinephrine autoreceptor subsensitivity following subchronic administration of -amphetamine

The effect produced by subchronic administration of -amphetamine ( -AMP) on the sensitivity of norepinephrine (NE) autoreceptors in the rat locus coeruleus (LC) was studied by means of single unit recording and microiontophoretic techniques. Twice daily i.p. administration of 5 mg/kg -AMP for one week markedly reduced the ability of i.v. -AMP and microiontophoretic application of clonidine to suppress the firing of LC NE neurons, suggesting strongly that NE autoreceptors became subsensitive. In addition, the firing pattern of NE neurons became ‘disorganized’ following subchronic AMP treatment.     

Electrophysiological identification of neurons in locus coeruleus

In 17 urethane-anesthetized rats 35 neurons, histologically verified as being situated in the locus coeruleus, were driven antidromically (latency, 44 msec) by electrical stimulation of the supracallosal bundle. Neurons of the locus coeruleus were also activated antidromically by stimulation of sites along the dorsal noradrenergic bundle in the midbrain (8-msec latency) and the hypothalamus (12-msec latency), and by stimulation of sites in the olfactory bulb (latency, 39 msec). Conduction velocity from these sites to the locus coeruleus was estimated to be 0.4 to 0.6 m/sec. Refractory periods of fibers in the dorsal noradrenergic bundle were determined at twice threshold and in the supracallosal bundle at intensities just above threshold; refractory periods ranging from 4 to 20 msec were observed. Because neurons both in and near the locus coeruleus were antidromically activated by stimulation of the dorsal noradrenergic bundle whereas stimulation of the supracallosal bundle antidromically activated only neurons in the locus coeruleus, stimulation of the dorsal noradrenergic bundle could not be used to identify locus coeruleus neurons. It is concluded that a subpopulation of neurons in the locus coeruleus can be identified by their slow, steady firing rate (2.6 per second) and long-latency antidromic response to stimulation of the supracallosal bundle. The electrophysiological properties of locus coeruleus neurons are considered in relation to neuroanatomical and functional studies of the locus coeruleus.     

Target cell stimulation and inhibition of norepinephrine uptake in dissociated rat locus coeruleus cultures

Primary cultures from dissociated locus coeruleus (LC) neurons of 14-day-old (E14) fetal rats were grown in vitro in serum complemented medium. Noradrenergic cells were identified using immunocytochemical staining for tyrosine hydroxylase (TH) antibody. Maturation of noradrenergic neurons was assessed by measuring the high-affinity uptake of [3H]norepinephrine (NE). The presence of hippocampal cells stimulated the specific uptake of [3H]NE by LC cells only when plated at low density. Increasing the concentration of hippocampal cells resulted in a 50% decrease in NE uptake by LC cells. A similar inhibitory effect was observed with striatal cells. The inhibition exerted by striatal cells appears to be developmentally regulated, with E18 exerting a stronger inhibitory effect than E15 striatum. The decrease in [3H]NE uptake in hippocampal-LC cocultures was due to a decrease in uptake by individual noradrenergic neurons. For a given plating density, the decrease in uptake of [3H]NE per noradrenergic cell in LC culture was only half the decrease in the cocultures, suggesting a target-associated effect rather than density-derived toxic effect. In culture conditions which favored neuronal but not glial survival, the stimulatory target effect was evident, and the inhibitory effect was absent. Medium conditioned by target glial cells had a marked stimulatory effect on [3H]NE uptake. Glial feader-layer had a strong inhibitory effect on [3H]NE uptake in serum-containing medium. We suggest that both neurons and glia mediate the target-stimulatory effect, whereas the inhibitory effect is mediated by direct contact between target glia and LC neurons.     

Changes in number of synapses and mitochondria in presynaptic terminals in the dentate gyrus following cerebral ischemia and rehabilitation training

Damage to the adult brain can result in adaptive plasticity in regions adjacent to the site of the principal insult and that the plastic changes may be modulated by post-injury rehabilitation training. In this study, we examined the effects of rehabilitation training on synaptic morphology in the dentate gyrus following transient global cerebral ischemia and the metabolic correlates of the ultrastructural changes. Forty adult male Wistar rats were included in the study and assigned to either ischemia or sham group. Following ischemic or sham surgery, rats were randomized to either complex environment housing (EC), exercise (EX), or social condition (SC, paired housing) group. Electron microscopy and unbiased stereological methods were used to evaluate synaptic plasticity and the number and size of mitochondria in synaptic axon terminals. Increased number of granule neurons was seen in all ischemic groups and in the sham EC rats. Changes in the number of synapses per neuron in the outer and inner molecular layers of the dentate gyrus parallel those seen in granule neurons. Similarly, ischemia and behavioral experience in EC independently increased the number of synaptic mitochondria in presynaptic terminals in both the outer and inner molecular layers; however, no significant changes were seen in mitochondrial size. These data suggest a link between behavioral training and synaptic plasticity in the region adjacent to the injury and that the likely metabolic correlate of this synaptic plasticity is increased number of mitochondria at synaptic axon terminals.     

Phorbol ester uncouples adenosine inhibition of presynaptic Ca2+ transients at hippocampal synapses

Synaptic transmission involves Ca2+ influx at presynaptic terminals. Adenosine receptors inhibit transmission, and this effect can be abolished by activation of PKC with phorbol esters. Whether protein kinase C (PKC) acts via alterations in Ca2+ entry at the presynaptic terminal is unknown. In the present study, we recorded the presynaptic Ca2+ transients (preCa(delta)) in hippocampal stratum radiatum, using fluorescence photometry. The calcium dye Fura-2 AM was used to load the Schaffer collateral/commissural tract and its terminals. Tetrodotoxin (TTX)-sensitive Na+ channels and Cd2+-sensitive, high-voltage activated Ca2+ channels (HVACCs) were required to elicit the preCa(delta). Application of the phorbol ester phorbol-12,13-dibutyrate (PDBu) abolished the adenosine inhibition of both preCa(delta) and the field excitatory postsynaptic potentials (fEPSPs). PDBu consistently potentiated fEPSPs, and also increased preCa(delta) in a large majority of the slices examined. Regardless of whether potentiation was observed, PDBu always prevented adenosine inhibition of preCa(delta). In contrast, the inactive phorbol ester, 4alpha-phorbol, did not alter adenosine inhibition of preCa(delta), indicating that PKC activation is necessary for the occurrence of the observed effects. Our findings suggest that PKC activation abolishes adenosine's inhibitory effect on synaptic activity involving presynaptic Ca2+ entry.     

Loss of axosomatic synapses in the dentate gyrus of aged rats

Axosomatic synapses involving granule cells of the dentate gyrus were studied by means of quantitative electron microscopic analysis in young adult (3-month-old) and aged (25-month-old) rats. The number of axosomatic synapses per unit length of neuronal soma membrane was found to be significantly lower (by 15%) in aged animals than in young adults. This decrease in synaptic numbers is not associated with age-related changes in the size of neuronal soma profiles or in the length of their plasma membranes. The ratio between the total length of synaptic appositions and the membrane length of a neuronal soma profile was diminished by 22% in aged rats, whereas the mean length of synaptic apposition was 10% less in these animals than in young adults. These data, taken together, suggest that an absolute loss of axosomatic synapses occurs with advanced age. It appears, therefore, than not only the loss of axodendritic synapses, described previously, but also the loss of axosomatic synapses, found here, contributes to the process of age-related partial deafferentation of neurons in the rat dentate gyrus.     

Fine structure of GABAergic neurons and synapses in the human dentate gyrus

Surgical tissue samples of the human dentate gyrus were immunostained for glutamate decarboxylase (GAD), the gamma-aminobutyric acid (GABA)-synthesizing enzyme, and studied by both light and electron microscopy. Immunoreactive neurons and terminals displayed similar morphological characteristics as known from studies in laboratory animals. Thus, GAD-positive neurons prevailed in the hilar region, whereas immunoreactive terminals were most frequently observed in the granular layer forming symmetric synaptic contacts with dendrites, cell bodies and axon initial segments of granule cells.     

Long- and short-term plasticity at mossy fiber synapses on mossy cells in the rat dentate gyrus

Mossy cells give rise to the commissural and associational pathway of the dentate gyrus, and receive their major excitatory inputs from the mossy fibers of granule cells. Through these feed-back excitatory connections, mossy cells have been suggested to play important roles in both normal signal processing in learning and memory, as well as in seizure propagation. However, the nature of the activity-dependent modifications of the mossy fiber inputs to mossy hilar cells is not well understood. We studied the long- and short-term plasticity properties of the mossy fiber-mossy cell synapse, using the minimal stimulation technique in slices in whole cell recorded mossy cells retrogradely prelabeled with the fluorescent dye DiO from the contralateral dentate gyrus. Following tetanic stimulation, mossy fiber synapses showed significant NMDA receptor-independent long-term potentiation (LTP), associated with increased excitatory postsynaptic currents (EPSC) amplitude and decreased failure rates. Coefficient of variance and failure rate analyses suggested a presynaptic locus of LTP induction. Mossy fiber synapses on mossy cells also showed activity-dependent short-term modification properties, including both frequency-dependent facilitation (stimuli at higher frequencies evoked larger EPSCs with lower failure rates) and burst facilitation (each EPSC in a burst had a larger amplitude and higher probability of occurrence than the preceding EPSCs within the burst). The data show that mossy fiber-mossy cell synapses exhibit both long- and short-term plasticity phenomena that are generally similar to the mossy fiber synapses on CA3 pyramidal cells.     

Morphological correlates of long-term potentiation imply the modification of existing synapses, not synaptogenesis, in the hippocampal dentate gyrus

This report evaluates two morphological markers of synaptogenesis following the induction of long-term potentiation (LTP) in the dentate gyrus of the anesthetized rat. These two morphological features, polyribosomes and multiple synaptic contacts, are known to increase in number with synaptogenesis in the mature hippocampus. The analysis focused on the middle third of the dentate molecular layer. As shown previously, this is the region of primary synaptic activation in our electrophysiological protocol and the region of localized morphological changes with LTP. Here the incidence of a polyribosome at the base of a dendritic spine declined 57% with LTP. In addition, the number of multiple synaptic contacts decreased 18% there with LTP. Both decreases were more pronounced immediately following conditioning stimulation than at later intervals. Because both morphological features decrease with LTP but increase with synaptogenesis, the data do not support the hypothesis that new synapses form with LTP. Instead, the data add further support to the view that the strengthening of existing excitatory synapses underlies LTP.     

Morphological alterations of the synapses in the locus coeruleus in Parkinson's disease

Parkinson's disease is the most common movement disorder in the broad spectrum of neurodegenerative diseases, associated frequently with gradual decline of the higher mental faculties. From the morphological point of view it is characterized by the degeneration of a substantial number of dopaminergic neurons of the substantia nigra and a considerable degeneration of neuronal networks in locus coeruleus, putamen, globus pallidus, thalamus and some areas of the cortex of the brain hemispheres. Filamentous inclusions, in the form of Lewy bodies and Lewy neuritis, composed mainly of alpha synuclein, been the hallmark of diffuse Lewy body dementia, have been described in the neurons of the substantia nigra in many cases of Parkinson's disease associated with dementia. In previous studies we have described the morphological alterations in the synapses in the caudate nucleus and the globus pallidus in cases of Parkinson's disease. In the present study we attempted to describe the morphological and morphometric alterations of the locus coeruleus in patients who suffered from Parkinson's disease with normal cognitive function and in patients who suffered from Parkinson's disease associated with dementia, comparing them with normal controls. The morphological alterations of the neurons, the dendrites, the retrograde axonic collaterals and the synapses were more impressive in cases of Parkinson's disease associated with dementia than in Parkinson's disease with normal cognitive function. The majority of the synapses demonstrated changes in size and shape of the pre- and postsynaptic components, polymorphism of the synaptic vesicles and marked morphological alterations of the mitochondria. The morphological alterations of the synapses in cases of Parkinson's disease associated with dementia, plead in favor of the importance of the neuronal circuits of locus coeruleus in cognitive functions.     

Electrophysiological characterisation of the dentate gyrus in five inbred strains of mouse.

Transgenic or knockout mouse models provide the opportunity to study the function of disease-related or novel genes. However, a confounding factor in all such research is the genetic and phenotypic variation of the mouse strain used to construct the models. A trait which is frequently studied in transgenic models of neurological disorders is synaptic transmission and plasticity of the dentate gyrus of the hippocampus. Consequently, we have investigated the variation in this trait across five strains of mouse (129 Ola, C3H, C57 albino, DBA/2, and FVB/N), in vivo. 129 Ola mice were found to have significantly larger maximal evoked EPSP slope and population spike amplitudes compared to the other strains. No differences across strains were found in paired-pulse facilitation of EPSP slope, a measure of pre-synaptic short-term plasticity. DBA/2 mice showed significantly reduced paired-pulse inhibition of population spike, a measure of poly-synaptic inhibitory feedback within the dentate gyrus. Potentiation of EPSP and population spike, following tetanic stimulation of the perforant path, was observed in all strains. However, DBA/2 mice showed a deficit in the maintenance of potentiation over 1 h, which confirms a previous report [S. Matsuyama, U. Namgung, A. Routtenberg, Long-term potentiation persistence greater in C57BL/6 than DBA/2 mice: predicted on basis of protein kinase C levels and learning performance, Brain Res. 763 (1997) 127-130]. These results show that electrophysiological traits do vary significantly across mouse strains, and that the selection of the strain may have a significant impact on results. Furthermore, since production of a transgenic or knock-out mouse frequently requires cross-breeding, care should be taken in establishing the contribution of parent strains to the final phenotype, as well as the potential interaction with the phenotype arising from the knock-out or transgene.     

Differential effect of norepinephrine upon granule cells and interneurons in the dentate gyrus

The effect of locally applied norepinephrine upon dentate granule cells and neighboring interneurons was examined in urethane-anesthetized rats. Norepinephrine inhibited the spontaneous firing of physiologically identified granule cells, but excited interneurons. These results demonstrate that two coexisting hippocampal cell types, which have many physiological properties and behavioral correlates in common, may be differentiated using a pharmacological criterion.     

AMPA receptor-mediated presynaptic inhibition at cerebellar GABAergic synapses: a characterization of molecular mechanisms

A major subtype of glutamate receptors, AMPA receptors (AMPARs), are generally thought to mediate excitation at mammalian central synapses via the ionotropic action of ligand-gated channel opening. It has recently emerged, however, that synaptic activation of AMPARs by glutamate released from the climbing fibre input elicits not only postsynaptic excitation but also presynaptic inhibition of GABAergic transmission onto Purkinje cells in the cerebellar cortex. Although presynaptic inhibition is critical for information processing at central synapses, the molecular mechanisms by which AMPARs take part in such actions are not known. This study therefore aimed at further examining the properties of AMPAR-mediated presynaptic inhibition at GABAergic synapses in the rat cerebellum. Our data provide evidence that the climbing fibre-induced inhibition of GABA release from interneurons depends on AMPAR-mediated activation of GTP-binding proteins coupled with down-regulation of presynaptic voltage-dependent Ca(2+) channels. A G(i/o)-protein inhibitor, N-ethylmaleimide, selectively abolished the AMPAR-mediated presynaptic inhibition at cerebellar GABAergic synapses but did not affect AMPAR-mediated excitatory actions on Purkinje cells. Furthermore, both G(i/o)-coupled receptor agonists, baclofen and DCG-IV, and the P/Q-type calcium channel blocker omega-agatoxin IVA markedly occluded the AMPAR-mediated inhibition of GABAergic transmission. Conversely, AMPAR activation inhibited action potential-triggered Ca(2+) influx into individual axonal boutons of cerebellar GABAergic interneurons. By suppressing the inhibitory inputs to Purkinje cells, the AMPAR-mediated presynaptic inhibition could thus provide a feed-forward mechanism for the information flow from the cerebellar cortex.     

Analysis of the presynaptic signaling mechanisms underlying the inhibition of LTP in rat dentate gyrus by the tyrosine kinase inhibitor,genistein

A great deal of recent evidence points to a role for tyrosine kinase in expression of LTP. Data have been presented that are consistent with the idea that tyrosine phosphorylation of proteins occurs in both the presynaptic and postsynaptic areas. In this study, we set out to investigate the role that tyrosine kinase might play presynaptically to modulate release of glutamate in an effort to understand the mechanism underlying the persistent increase in release that accompanies LTP in perforant path-granule cell synapses. We report that LTP was associated with increased calcium influx and glutamate release. LTP was also associated with an increase in phosphorylation of the alpha-subunit of calcium channels and ERK in synaptosomes prepared from dentate gyrus, and these effects were inhibited when LTP was blocked by the tyrosine kinase inhibitor, genistein. LTP was accompanied by increased protein synthesis and increased phosphorylation of CREB in entorhinal cortex, effects that were also blocked by genistein. We conclude that tetanic stimulation leads to enhanced tyrosine phosphorylation of certain presynaptically located proteins that modulate glutamate release and contribute to expression of LTP.