Inhibitory and indirect excitatory effects of dopamine on sympathetic preganglionic neurones in the neonatal rat spinal cord in vitro

Regions of the thoraco-lumbar spinal cord containing sympathetic preganglionic neurones are rich in dopamine terminals. To determine the influence of this innervation intracellular recordings were made from antidromically identified sympathetic preganglionic neurones in (400 micrometers) transverse neonatal rat spinal cord slices. Dopamine applied by superfusion caused a slow monophasic hyperpolarisation in 46% of sympathetic preganglionic neurones, a slow monophasic depolarisation in 28% of sympathetic preganglionic neurones and a biphasic effect consisting of a slow depolarisation followed by a slow hyperpolarisation or vice-versa in 23% of sympathetic preganglionic neurones. Three percent of sympathetic preganglionic neurones did not respond to the application of dopamine. Low Ca2+/high Mg2+ Krebs solution or TTX did not change the resting membrane potential but abolished the slow depolarisation elicited by dopamine, indicating this was synaptic and did not prevent the dopamine induced hyperpolarisation. The dopamine induced slow hyperpolarisation was mimicked by the selective D1 agonists SKF 38393 or SKF 81297-C and blocked by superfusion with the D1 antagonist SCH 23390. It was not prevented by superfusion of the slices with alpha1 or alpha2 or beta-adrenoceptor antagonists, whereas the inhibitory or excitatory actions of adrenaline were prevented by alpha1 or alpha2 antagonists, respectively. The dopamine induced slow depolarisation occurring in a sub-population of sympathetic preganglionic neurones was mimicked by quinpirole, a D2 agonist, and blocked by haloperidol, a D2 antagonist. Haloperidol did not block the dopamine induced hyperpolarisations. Dopamine also induced fast synaptic activity which was mimicked by a D2 agonist and blocked by haloperidol. D1 agonists did not elicit fast synaptic activity.     

Excitatory and indirect inhibitory actions of 5-hydroxytryptamine on sympathetic preganglionic neurones in the neonate rat spinal cord in vitro

The action of 5-hydroxytryptamine (5-HT) on sympathetic preganglionic neurones (SPN) was studied by intracellular recordings in thin slices of neonatal rat spinal cord in vitro. Superfusion of 5-HT (1–270 μM) to SPN caused a concentration dependent slow depolarization or inward current and an increase in synaptic activity consisting of both EPSPs and IPSPs. The slow depolarization was still present after superfusion with TTX. Similar effects were seen during superfusion with 5-carboxamidotryptamine (5-CT) or -methyl-5-hydroxytryptamine (-me-5-HT). A comparison with the potency of 5-HT was made for 5-CT or -me-5-HT on the same neurone by determining the magnitude of the slow depolarization to different concentrations of agonist. This showed that the apparent potency of the agonists was 5-CT> 5-HT> -me-5-HT even in the presence of fluoxetine, a 5-HT uptake inhibitor. The 5-HT-induced slow depolarization was partially blocked by ketanserin but full recovery was not observed. The results suggest that the excitatory action of 5-HT on SPN is mediated via an atypical 5-HT₂ receptor or a 5-HT_1C-like receptor. The 5-HT-induced IPSPs were reversibly blocked by superfusion with strychnine, suggesting they were mediated by glycine.     

Sympathetic preganglionic neurons in the isolated spinal cord of the neonatal rat

A preparation of the isolated spinal cord of the neonatal rat was developed for the study of sympathetic preganglionic neurons (PGNs). PGNs were identified for extracellular single unit recording by their location and by antidromic activation by ventral root stimulation. PGNs could be synaptically activated by stimulation of the dorsal root and spinal pathways. Spontaneous firing was observed in 18% of the PGNs. The average firing rate was 1 Hz with a range of 0.3 to 2 Hz.PGNs (and motoneurons) were visualized by incubating vental roots in horseradish peroxidase (HRP) solutions. The location and morphology of PGNs were similar to those reported in studies using adult animals. Primary afferent fibers were visualized by incubating dorsal roots in HRP solutions. Dorsal root projections appeared mature in the neonatal rat. Primary afferents did not appear to project directly to PGNs.It is concluded that PGNs are viable in this preparation and that spinal sympathetic systems are relatively mature in the neonatal rat.     

Participation of excitatory amino acid receptors in the slow excitatory synaptic transmission in rat spinal dorsal horn

In a rat spinal slice preparation the participation of excitatory amino acid (EAA) receptors in the responses of deep dorsal horn neurons to repetitive stimulation of lumbar dorsal roots was investigated using 3 EAA receptor antagonists, kynurenic acid, D-(-)-2-amino-4-phosphonovaleric acid (D-APV) and 6-cyano-2,3-dihydroxy-7-nitroquinoxaline (CNQX) and current-clamp and voltage-clamp techniques. We found that the slow excitatory synaptic response evoked by 10-20 Hz electrical stimulation of primary afferent fibers consisted of two depolarizing components: an initial component lasting 1-5 s and a late one of 1-3 min duration. The initial and late components of the slow excitatory synaptic response can also be distinguished on the basis of their voltage-dependence and sensitivity to Mg2+ ions, kynurenate, D-APV and CNQX. In the presence of Mg2+, the initial component of the slow excitatory synaptic response increased with membrane hyperpolarization, whereas the late component decreased in most of the cells examined. In a zero-Mg2+ medium, the initial component was potentiated, but the late component was reduced. In both transverse and longitudinal spinal cord slices perfused with 1.2 mM Mg(2+)-containing medium, bath application of kynurenic acid (0.1-0.5 mM), D-APV (0.05-0.1 mM) and CNQX (5-7 microM) caused a reversible reduction of the peak amplitude of the initial slow depolarizing component that was greater in transverse (kynurenic acid: by 92.6 +/- 5.0%; D-APV: by 69.1 +/- 7.8%; CNQX: by 76.6 +/- 9.8%) than in longitudinal slices (kynurenic acid: by 53.3 +/- 1.3%; D-APV: by 31.5 +/- 9.1%; CNQX: by 35.3 +/- 11.1%). In contrast, all 3 antagonists of EAA receptors produced no consistent change in the peak amplitude or half-duration of the late depolarizing component of the slow excitatory synaptic response. Our results obtained with EAA receptor antagonists, at resting membrane potentials, in the absence and presence of Mg2+ and synaptic inhibition, indicate that the synaptic activation of the NMDA- and non-NMDA-receptor systems of deep spinal dorsal horn neurons by repetitive stimulation of primary afferent fibers may be selectively involved in the mediation of the initial, but not the late depolarizing component of the slow excitatory synaptic response.     

Effects ofl-cysteine-sulphinate andl-aspartate, mixed excitatory amino acid agonists, on the membrane potential of cat caudate neurons

Responses evoked byl-cysteine-sulphinate (l-CSA) andl-aspartate (l-Asp) were recorded with intracellular electrodes from caudate neurons in halothane anesthetized cats.l-CSA andl-Asp were applied microiontophoretically to caudate cells and their effects on membrane and action potentials, as well as on cortically evoked synaptic potentials were evaluated.l-CSA andl-Asp induced depolarizations accompanied by regular firing resembling kainate (KA)- or quisqualate (QUIS)-induced excitation patterns (type 1) in 82% and 72% of the recorded neurons, respectively, and a mixed pattern consisting of aN-methyl-d-aspartate (NMDA)-like excitation (type 2) followed by a regular type 1 pattern in the remaining cells. In about a quarter of the cells the effects ofl-CSA andl-Asp, but not those of KA or QUIS, were partially antagonized by 2-amino-7-phosphonoheptanoate (AP-7), a specific NMDA receptor antagonist. Kynurenate, a broad spectrum excitatory amino acid antagonist, blocked responses elicited by eitherl-CSA or QUIS. The actions ofl-CSA andl-Asp on the firing pattern and membrane potential of cat caudate neurons in situ provide evidence in favor of their mixed agonist nature with respect to NMDA and non-NMDA excitatory amino acid receptors.     

Intrathecal administration of non-NMDA receptor agonists increases arterial pressure and heart rate in the rat

We have found that spinal NMDA receptors are involved in control of sympathetic output in pathways to the heart and vessels. The present study was done to determine whether spinal non-NMDA excitatory amino acid receptors participate in cardiovascular regulation. Experiments were done on urethane-anesthetized Sprague-Dawley rats, giving the non-NMDA receptor agonists, quisqualate and kainate, and the antagonist, kynurenate, intrathecally at the spinal T9 level. Both quisqualate (30 nmol; n = 7; to activate AMPA receptors) and kainate (2 nmol; n = 6; to activate K receptors) increased arterial pressure and heart rate. The responses were characterized by a rapid onset, achieving, in most cases, greater than 80% of the maximum response within 1-4 min, and a persistence throughout the remaining 20-24 min of the experiment. I.v. injection of hexamethonium (10 mg/kg) prevented the effects of intrathecal administration of quisqualate (n = 5) but not of kainate (n = 7). To determine whether the hexamethonium-resistant effects of kainate were due to a peripheral action, kainate was given i.v. (n = 6); it was found to be without effect on arterial pressure or heart rate. The increases in arterial pressure and heart rate produced by intrathecal administration of quisqualate (30 nmol; n = 6), kainate (2 nmol; n = 6), glutamate (1 mumol; n = 6) and NMDA (2 nmol; n = 6) but not carbachol (27.4 nmol; n = 6) were prevented by similar preadministration of kynurenate (125 nmol). Intrathecal administration of kynurenate (125 nmol; n = 6; 500 nmol; n = 7) decreased arterial pressure and/or heart rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ethanol reduces neuronal excitability and excitatory synaptic transmission in the developing rat spinal cord

Effects of acute ethanol (EtOH) exposure on motoneuron excitability and properties of synaptic transmission were examined in spinal cords of postnatal rats. Whole-cell patch clamp recordings and intracellular recordings with high-resistance electrodes were carried out in motoneurons of 1- to 4-day-old postnatal rats. To determine the effects of extracellular EtOH on action potential waveform, properties of current-evoked soma action potentials and motoneuron ability to generate repetitive action potential firing were examined. During a brief EtOH (70 mM) exposure, larger depolarizing current was required for action potential generation, the duration of the after hyperpolarizing potential increased, and fewer action potentials were produced during a prolonged intracellular current injection. These effects were reversed within 20 min of EtOH removal from the extracellular solution. To determine whether the reduced probability of action potential generation was associated with changes in synaptic transmission, properties of evoked synaptic potentials and spontaneous synaptic currents were investigated. In the presence of EtOH, the amplitude of dorsal root-evoked synaptic potentials was reduced, the frequency of spontaneous excitatory postsynaptic currents decreased, while the frequency of inhibitory postsynaptic currents increased. Our data suggested that acute EtOH exposure suppressed motoneuron electrical activity by decreasing motoneuron excitability and shifting the balance between excitatory and inhibitory synaptic transmission toward inhibition.     

Antagonists of synaptic and amino acid excitation of neurones in the cat spinal cord

In the spinal cord of the anaesthetized cat microelectrophoretically administered (+/-)-cis-2,3-piperidine dicarboxylate (2,3-PDA), (+/-)-cis-2,5-piperidine dicarboxylate (2,5-PDA), gamma-D-glutamylglycine (gamma DGG), beta-D-aspartyl-beta-alanine (beta DAA), (+/-)-2-amino-4-phosphonobutyrate (2-APB), (+/-)-2-amino-5-phosphonovalerate (2-APV) and (+/-)-2-amino-7-phosphonoheptanoate (2-APH) were assessed as antagonists of chemical excitation of dorsal horn interneurones and Renshaw cells by N-methyl-D-aspartate (NMDA), L-aspartate, quisqualate (QUIS), kainate and L-glutamate, and of monosynaptic and polysynaptic excitation by impulses in primary afferent fibres of muscle and cutaneous origin. Whereas polysynaptic excitation of interneurones was readily and reversibly depressed by 2-APV, 2-APH, beta DAA, gamma DGG and 2,3-PDA, all of which also reduced excitation by NMDA (and L-aspartate) more than that by QUIS (and L-glutamate), no selective antagonism of monosynaptic excitation could be demonstrated. In particular, 2,3-PDA, which depressed excitation by kainate to a greater extent than that by either QUIS or NMDA, appeared to have no effect on monosynaptic excitation. The results support the involvement of L-aspartate as the transmitter of some spinal excitatory interneurones, but none of the antagonists tested were considered suitable for assessing the role of L-glutamate as the transmitter of some spinal primary afferent fibres.     

[H]Prazosin binding in the intermediolateral cell column and the effects of iontophoresed methoxamine on sympathetic preganglionic neuronal activity in the anaesthetized cat and rat

The autoradiographic localization of [³H]prazosin (α₁-adrenoceptor ligand) binding sites was determined in cat spinal cord sections. High levels of [³H]prazosin binding were found in the intermediolateral cell column (IML) at thoracic and lumbar levels. The iontophoresis of theα₁-adrenoceptor agonist methoxamine onto sympathetic preganglionic neurones (SPNs) in anaesthetized cats and rats caused excitation of 8 cat SPNs and 13 rat SPNs. These results suggest an excitatory role for some of the catecholaminergic of the IML.     

Effects of neonatal adrenalectomy on 5-HT and TRH-Like immunoreactivity in the rat spinal cord

This study investigated the effects of neonatal unilateral adrenalectomy on the serotonin- (5-HT) and thyrotropin-releasing hormone-like immunoreactivities (TRH-LI) in the intermediolateral cell column (IML) of the rat spinal cord where the sympathetic preganglionic neurons innervating the adrenal medulla are located. The density of the innervation was measured by a computer-assisted image analysis. Two weeks after the lesion, only one rat (1/3) showed a 30% decrease of 5-HT-LI in the ipsilateral IML, although no modifications were observed for TRH-LI. At 1 month, we observed a variable decrease of 19% to 30% for either 5-HT- or TRH-LI in the ipsilateral IML. However, one animal (1/3) showed nonsignificant modifications. At 3 months, we showed a 17% mean loss of 5-HT-LI and TRH-LI in the ipsilateral IML. However, the decreases of 5-HT-LI and TRH-LI did not always appear similar. These results appear different from those obtained after neonatal removal of the superior cervical ganglion.     

Long duration ventral root potentials in the neonatal rat spinal cord in vitro; the effects of ionotropic and metabotropic excitatory amino acid receptor antagonists.

Long duration, primary afferent evoked ventral root potentials (VRP's) have been recorded in vitro from hemisected spinal cords prepared from 8-12-day-old rat pups. Single shock stimulation of a dorsal root at stimulus strengths sufficient to recruit C/group IV afferent fibres evoked a long duration (11.9 +/- 1.2 s) ipsilateral VRP in all preparations. This long duration VRP consisted of two components, (i) a slow wave, time to peak 137.0 +/- 5.1 ms, the amplitude of which was reduced to 8.7% of mean control value in the presence of the N-methyl-D-aspartate (NMDA) antagonist D-AP5 (40 microM), (ii) a prolonged wave with a time to peak of 2.0 +/- 0.2 s which was partially resistant to D-AP5 (40 microM). Both the slow and the prolonged waves were unaffected following superfusion with the metabotropic excitatory amino acid (EAA) receptor antagonist L-AP3 (100-200 microM). Low frequency (1-10 Hz) repetitive stimulation (20 s duration) of high threshold dorsal root afferents evoked a temporal summation of synaptic activity which generated a progressively depolarizing VRP. This cumulative VRP was graded with frequency of stimulation (0.89 +/- 0.13 to 1.25 +/- 0.19 mV). The cumulative VRP was followed by a post-stimulus depolarization which outlasted the period of repetitive stimulation by tens of seconds (47.6 +/- 8.4 to 91.2 +/- 19.9 s). In the presence of AP5 the amplitude of the cumulative VRP was depressed to 54.5 +/- 11.5% of control values when low frequency (1.0 Hz) stimulation was used. The proportion of the cumulative VRP resistant to D-AP5 increased as the frequency of stimulation was increased to 10 Hz. The decay time of the post-stimulus depolarization was unaffected by AP5. Neither the amplitude nor the post-stimulus depolarization of the cumulative VRP was affected by 200 microM L-AP3. It is suggested that both an AP5 sensitive and AP5 insensitive potential contribute to the long duration VRP evoked in the neonatal rat spinal cord following single shock high threshold afferent stimulation. Moreover, the AP5 insensitive prolonged depolarization is manifest following sustained low frequency stimuli and higher frequency inputs.     

Induction of c-fos gene expression by spinal cord transection in the rat

Sympathetic nerve activity is maintained after high spinal injury through circuits that remain in question. We evaluated patterns of c-fos gene induction as a monitor of spinal neurons responding to high spinal cord transection in the rat. Rats were anesthetized with isofluorane. Lower cervical or upper thoracic spinal segments were exposed, immersed in warm mineral oil and transected. Spinal cords were exposed but not transected in anesthetized controls. After 2.5 h, spinalized and control rats were perfused for immunocytochemistry. Cervical and thoracolumbar spinal segments and dorsal root ganglia were sectioned coronally. Tissues were incubated in primary, polyclonal antisera raised in rabbit or sheep against a peptide sequence unique to the N-terminal domain of Fos, and processed immunocytochemically. Neurons were induced to express Fos-like immunoreactivity (FLI), bilaterally, in the spinal gray, but not in primary sensory ganglia. Spinal cord transection induced neurons to express FLI in thoracic laminae I, IIo (outer substantia gelatinosa). Vre (lateral reticulated division), VII (lamina intermedia) and X, and the intermediolateral cell column. Lamina VIII was also labeled in spinal-injured but not in control animals. Immunolabeled nuclei were prominent in lumbar segments and were concentrated in the medial third of laminae I and IIo, and in laminae VII and X. Few cells were labeled in upper cervical or sacral segments. FLI was sparse in the spinal gray of controls and expressed mainly within the dorsal root entry zone of upper thoracic segments. Patterns of c-fos gene expression were site-specific and correlated with laminae that respond predominantly to noxious stimulation and that contain sympathetic interneurons. Laminae that are responsive to non-noxious stimuli and activated by walking, IIi, nucleus proprius, medial V and layer VI were not induced to express FLI. We conclude that neurons in specific spinal laminae that process high threshold afferents and that harbor neurons with sympathetic nerve-related activity are activated selectively by spinal cord transections. We hypothesize that peripheral afferents processed by spinal-sympathetic circuit neurons may regulate sympathetic discharge in the absence of supraspinal drive.     

Cuneiform nucleus stimulation-induced sympathoexcitation: role of adrenoceptors, excitatory amino acid and serotonin receptors in rat spinal cord

Stimulation of the midbrain cuneiform nucleus has previously been shown to produce increases in arterial blood pressure and lumbar sympathetic nerve activity. While this sympathoexcitatory effect is, in part, due to excitation of premotor sympathoexcitatory neurons in the rostral ventrolateral medulla, the specific spinal neurotransmitter systems recruited by cuneiform nucleus stimulation remains to be elucidated. In this study, mean arterial pressure, resting and cuneiform nucleus stimulation-evoked lumbar sympathetic nerve activity were analysed following intrathecal injections of an excitatory amino acid antagonist (kynurenic acid), α₁-adrenoceptor antagonist (prazosin) and a serotonin receptor antagonist (methiothepin) in anesthetized, paralysed male Sprague-Dawley rats. Mean arterial pressure and resting sympathetic nerve discharge were decreased by all treatments (n=6/group) compared to the vehicle control group. Intermittent electrical stimulation of the cuneiform nucleus produced a bimodal sympathoexcitatory response, of which the short latency peak was significantly attenuated (43% reduction) by intrathecal kynurenate whereas the long latency peak was reduced by intrathecal prazosin (decrease of 21%) and methiothepin (38% attenuation). These results are consistent with the significant roles of excitatory amino acid, α₁-adrenergic and serotonin receptors in modulating the activity of sympathetic vasomotor preganglionic neurons supplying the lumbar sympathetic nerve trunk, and suggest the existence of at least three neuronal groups and/or pathways associated with the sympathoexcitatory response to cuneiform nucleus stimulation.     

Mechanisms mediating the sympathetic silent period: Studies in the isolated spinal cord of the neonatal rat

The properties of the sympathetic silent period were examined using the isolated spinal cord of the neonatal rat. In all spontaneously active sympathetic preganglionic neurons (PGN) examined, repetitive stimulation of the ventral root gave rise to a prolonged inhibition (up to 30 s) of spontaneous activity. The silent period could also be demonstrated in most 'silent' PGN using a condition-test paradigm. The characteristics of the silent period in this preparation resembled those previously reported in the adult cat. Using several paradigms, we were able to show a dissociation between the duration of the silent period and the recent firing history of the PGN. This indicates that the silent period is not due solely to recovery processes intrinsic to the PGN. By stimulating adjacent ventral roots or rostral and caudal bundles of the same ventral root, we found that the system producing the silent period was confined to a restricted anatomical locus. Activation of the silent period was capable of inhibiting glutamate-evoked activity, implying that the inhibition impinges directly on the PGN. We found no evidence of a cholinergic mediation of the silent period. However, experiments with naloxone indicated that opiate mechanisms play an unsuspected role in modulating the silent period. We conclude that at least some component of the silent period is mediated by a synaptic mechanism extrinsic to the PGN.     

Substance P and NMDA receptors mediate a slow nociceptive ventral root potential in neonatal rat spinal cord

Substance P and glutamate actions have separately been implicated in the generation of nociceptive-related slow ventral root potentials (slow VRPs). We report that slow VRPs are dependent on both substance P and NMDA receptor-mediated neurotransmission. Slow VRPs of 10-40 s duration were evoked by electrically stimulating a lumbar dorsal root and recorded at the corresponding ipsilateral ventral root in spinal cords isolated from 1- to 5-day-old rats; the monosynaptic reflex was also recorded. The NMDA receptor antagonist APV (5-20 microM) and the substance P antagonist spantide (10-20 microM) both reversibly depressed the slow VRP without affecting the monosynaptic reflex; spantide and APV applied together nearly abolished the slow VRP. The quisqualate-kainate receptor antagonist CNQX (1-5 microM) reduced the monosynaptic reflex and an early component of the slow VRP. A slow VRP could be elicited by brief (0.1-1.0 s) focal applications of either substance P (2-20 microM) or NMDA (10 microM), and also by CGRP (2-20 microM). Substance P-evoked and NMDA-evoked responses were blocked by their respective antagonists spantide and APV. Each was also cross-sensitive to the other antagonist. Both excitatory amino acids, acting on an NMDA receptor, and substance P, acting on a tachykinin receptor, thus appear to be involved in generating this slow potential. Both NMDA and tachykinin receptors are necessary to generate a full response.     

The role of putative excitatory amino acid neurotransmitters in the initiation of locomotion in the lamprey spinal cord. I. The effects of excitatory amino acid antagonists

The activation of N-methyl-D-aspartate (NMDA) and kainate receptors will evoke fictive locomotion in the appropriate motor pattern for locomotion in the isolated lamprey spinal cord, but not a selective activation of quisqualate receptors. The present experiments test whether the initiation of locomotion in response to sensory stimulation depends on these types of receptors. An in vitro preparation of the lamprey spinal cord with part of its tailfin left innervated has been used. In this preparation a sequence of fictive locomotion (i.e. alternating bursts in the segmental ventral roots with a rostrocaudal phase lag) can be elicited by continual sensory stimulation of the tailfin. The effects of excitatory amino acid antagonists were studied by recordings from ventral roots (extracellularly) and motoneurones (intracellularly). It was found that the strong initial bursts of each swimming sequence induced by sensory stimulation were depressed by combined NMDA/kainate antagonists (cis-2,3-piperidine dicarboxylate (PDA) and gamma-D-glutamylglycine (gamma-DGG] whereas the less intense burst activity, occurring particularly towards the end of each swimming sequence, was depressed by a selective NMDA antagonist, 2-amino-5-phosphonovalerate (2-APV). This condition could be mimicked in an isolated spinal cord preparation by an application of L-glutamate; the low-level fictive locomotion induced by low doses of L-Glu (less than 100 microM) was depressed by a NMDA antagonist (2-APV), and, if higher doses were applied, the activity was only depressed by PDA/gamma-DGG. The mode and time course of the depression (by excitatory amino acid antagonists) of fictive locomotion, induced by sensory stimulation, shows that the putative excitatory amino acid neurotransmitter directly or indirectly acts at the pattern generating circuitry within the spinal cord.     

A sealed cranial window system for simultaneous recording of blood flow, and electrical and optical signals in the rat barrel cortex

The dorsal commissural nucleus (DCN) in the lumbosacral spinal cord (L6–S1) receives primary afferent fibers from both pelvic and pudendal nerves in rats. However, the physiological and pharmacological properties of synaptic responses of the DCN neurons to stimulation of those nerves remain unclear. We have developed a longitudinal spinal cord (L6–S1) slice preparation from mature rats that retained both nerves attached. Blind whole-cell recordings were made from the DCN neurons in this preparation. In most neurons, mono- and/or poly-synaptic fast excitatory postsynaptic potentials (EPSPs) were evoked by electrical stimulation of either the pelvic or pudendal nerve. These EPSPs were mediated by activation of Aβ/Aδ and/or C fibers (conduction velocities, 0.5–17.3 m/s), and were abolished by CNQX. Fast EPSPs elicited by either pelvic or pudendal nerve stimulation were occasionally accompanied by bicuculline- and strychnine-sensitive IPSPs. In one-third of the neurons tested, mono- and/or poly-synaptic EPSPs were elicited by the stimulation of both the pelvic and pudendal nerves, indicating convergence of the visceral and somatic primary afferent inputs from the pelvic region onto the DCN neurons. The preparation is applicable to study the mechanism of the integration of the visceral and somatic inputs in the spinal cord.     

Comparative effects of neonatal hypothyroidism and euthyroidism on TRH and substance P content of lumbar spinal cord in saline and PCPA-treated rats

The effects of neonatal thyroidectomy and thyroid hormone replacement therapy on the content of substance P and TRH in the lumbar segment of the rat spinal cord were studied. The peptide content of discrete spinal cord regions removed by punches of frozen serial slices was measured by RIA. Animals receiving T4 replacement therapy were indistinguishable from normal littermates. In hypothyroid animals without PCPA-treatment, levels of TRH and substance P were significantly increased by 100% in the ventral and the dorsal lumbar spinal cord, respectively. Inhibition of serotonin biosynthesis by PCPA increased by 90% the substance P content in the dorsal horn of euthyroid rats and abolished completely the stimulatory effect of hypothyroidism on the TRH content of the ventral horn. These findings suggest the existence of a physiological relationship between substance P and TRH with the serotoninergic system in the rat spinal cord and that thyroid hormone is implicated in the normal development of the peptide-containing neurons in the rat spinal cord.     

The role of putative excitatory amino acid neurotransmitters in the initiation of locomotion in the lamprey spinal cord. II. The effects of amino acid uptake inhibitors

Fictive locomotion can be evoked in an in vitro preparation of the lamprey spinal cord by an activation of N-methyl-d-aspartate (NMDA) or kainate receptors. To obtain further knowledge of the putative transmitters underlying this activation the effects of l-glutamate and l-aspartate were examined. These endogenous amino acids exerted a distinctly different effect as compared to the synthetic amino acids (N-methyl-d, l-aspartate and kainate) previously tested. In a wide dose range l-glutamate and l-aspartate elicited fictive locomotion only when the bathing solution was rapidly circulated over the spinal cord surface. In the absence of fluid circulation the activity rapidly ceased. To test if this effect was due to an uptake of amino acids, two amino acid uptake inhibitors were administered. After exposure to p-chloromercuriphenylsulphonate (pCMS) or dihydrokainate (DHK), l-glutamate and l-aspartate elicited continuous fictive locomotion independently of whether the bathing fluid was circulated or not. This treatment also markedly lowered the threshold doses of l-glutamate and l-aspartate, while the effects of NMA and kainate were barely affected. Fictive locomotion induced by sensory stimulation of the tailfin was also prolonged by dihydrokainate. These findings suggest that a highly effective amino acid uptake system is present in the lamprey spinal cord and furthermore that it takes part in the inactivation of synaptically released acidic amino acid neurotransmitters, which are of importance for the initiation of locomotion.     

Developmental and stimulus-specific expression of the immediate-early genezif268 in rat spinal cord

Expression of the cellular immediate-early gene,zif268, was investigated using immunocytochemical methods in cervical spinal cord of neonatal and adult rats. The postnatal expression ofzif268 follows a specific temporal and spatial sequence in the spinal dorsal horn. Neurons immunoreactive for Zif268 protein were not present in cervical spinal cord before postnatal day (P) 6. At P6 they were occasionally observed in Rexed's lamina I. By P11, a few additional, faintly labeled, Zif268-positive neurons appeared in lamina III. Around P16, however, many immunoreactive neurons were found in laminae I–III and a few in laminae IV–VIl. The number of Zif268-immunoreactive neurons decreased markedly by P21 and was further reduced by P26 to become virtually absent in adult rats. In adults, surgical exposure of peripheral nerves alone enhanced Zif268 expression, but this effect largely disappeared in less than 6 h. Electrical stimulation of the nerves with high-frequency long trains, typical of those known to elicit long-term neural plasticity, induced a marked increase in Zif268 expression in the dorsal horn. Stimulation with single pulses had a much weaker effect. Zif268 may thus play a role in stimulus-induced, long-term neural plasticity in the spinal cord.