The European journal of neuroscience
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Primary cultures of neonatal rat dorsal root ganglion (DRG) neurons were used to examine the mechanisms underlying both the direct activation and the sensitization of sensory neurons by prostanoids. Prostaglandin E2 (PGE2) elevated cytosolic calcium concentration ([Ca2+]i) in a subpopulation of small (< 19 microm) diameter, capsaicin-sensitive DRG neurons. PGE2 also stimulated substance P (SP) release from DRG cultures. ⋯ PGE2 stimulated adenylyl cyclase activity in DRG cultures, at concentrations and times consistent with those required to observe both the direct and sensitizing effects of the prostanoid on [Ca2+]i responses. Furthermore, the direct and sensitizing effects of PGE2, on both [Ca2+]i responses and SP release, were mimicked by the membrane permeant cAMP analogue dibutyryl cAMP and inhibited by H89, an inhibitor of cAMP-dependent protein kinase A (PKA). These observations are consistent with the hypothesis that both direct activation and sensitization of sensory neurons by prostanoids, such as PGE2, are mediated by PKA-dependent phosphorylation mechanisms.
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Previous studies have reported that the alpha1-adrenergic system can activate spinal rhythm generators belonging to the central respiratory network. In order to analyse alpha1-adrenergic effects on both cranial and spinal motoneuronal activity, phenylephrine (1-800 microM) was applied to in vitro preparations of neonatal rat brainstem-spinal cord. High concentration of phenylephrine superfusion exerted multiple effects on spinal cervical outputs (C2-C6), consisting of a lengthening of respiratory period and an increase in inspiratory burst duration. ⋯ However, only nonrespiratory motoneurons showed additional rhythmic membrane depolarizations (with spiking) occurring in phase with the slow motor rhythm recorded from the ventral root. Furthermore the tonic depolarization produced in all motoneurons results from an inward current [which persists in the presence of tetrodotoxin (TTX)] associated with a decrease in neuron input conductance, with a reversal potential varying as a Nernstian function of extracellular K+ concentration. Our results indicate that the alpha1-adrenoceptor activation: (i) affects both the central respiratory command (i.e. respiratory period and inspiratory burst duration) and spinal inspiratory outputs; (ii) induces slow spinal motor rhythmicity, which is unlikely to be related to the respiratory system; and (iii), increases motoneuronal excitability, probably through a decrease in postsynaptic leak K+ conductance.
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Neural activity influences the patterning of synaptic connections and functional organization of developing sensory and motor systems, but the long-term consequences of intense neural activity such as seizures in the developing hippocampus are not adequately understood. To evaluate the possibility that abnormal neural activity during early development may have long-term functional effects in hippocampal circuitry that plays a role in learning, memory and epilepsy, functional properties of hippocampal circuitry were assessed in adult rats that had experienced seizures induced by kainic acid on specific days during early postnatal development. Although previous studies have suggested that the immature hippocampus is relatively resistant to seizure-induced alterations compared with adults, independent behavioural and physiological experiments demonstrated that seizures evoked by kainic acid during early postnatal development induced a long-term loss of hippocampal plasticity manifesting as reduced capacity for long-term potentiation, reduced susceptibility to kindling, and impaired spatial learning, which was associated with enhanced paired-pulse inhibition in the dentate gyrus. The enhancement of inhibition and loss of plasticity were maximal when the seizures occurred on the first day of life, but were also observed when seizures were induced as late as postnatal day 14, which delimited a period of postnatal susceptibility in the developing rat hippocampus when disruption of normal neural activity by seizures produced consistent effects on a hippocampal-dependent behaviour and several forms of hippocampal plasticity implicated in learning, memory and the development of epilepsy in adulthood.
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Serving as the ventral, extra-thalamic relay from the brainstem reticular activating system to the cerebral cortex, basal forebrain neurons, including importantly the cholinergic cells therein, are believed to play a significant role in eliciting and maintaining cortical activation during the states of waking and paradoxical sleep. The present study was undertaken in rats to examine the effects upon electroencephalogram (EEG) activity and sleep-wake state of inactivating basal forebrain neurons with microinjections of procaine versus activating them with microinjections of agonists of glutamate, which is the primary neurotransmitter of the brainstem reticular activating system. Microinjections into the basal forebrain were performed using a remotely controlled device in freely moving, naturally sleeping/waking rats during the day when they are asleep the majority of the time. ⋯ In addition, NMDA, which has been shown in vitro to induce rhythmic bursting in the cholinergic cells, significantly increased theta activity. Following the microinjections of NMDA, c-Fos protein, which has been shown to reflect neural activity, was found in numerous cholinergic, and also GABAergic (gamma-aminobutyric acid) and other non-cholinergic neurons, in the substantia innominata and magnocellular preoptic nucleus near the microinjection cannulae. These results substantiate the role of cholinergic, possibly together with other, basal forebrain neurons in cortical activation, including elicitation of gamma and theta activities that underlie cortical arousal during waking and paradoxical sleep.
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Various hypotheses have been proposed to account for the mechanical hyperalgesia and spontaneous pain seen in animal models of peripheral neuropathy. The purpose of the present study was to determine whether there exists a spinal neuronal correlate to these properties. An experimental neuropathy was induced in male Sprague-Dawley rats by placing a 2-mm PE-90 polyethylene cuff around the sciatic nerve. ⋯ There may be a redistribution of membrane-bound ion channels, predominantly sodium channels, which leads to ectopic activity and thus spontaneous discharge of dorsal horn neurons. With regard to mechanical stimulation-evoked synaptic input, the central terminals of myelinated afferents expand into regions of the spinal cord which normally receive their predominant input from unmyelinated nociceptive afferents. This may be coupled with a change in these myelinated afferents so that they now synthesize and release peptides, primarily substance P, from their central terminals with the result that the effects of their chemical mediators of synaptic transmission add to the effects of nociceptive inputs leading to exaggerated responses to painful stimuli, thus the basis of clinical hyperalgesia.