Actions of glutamic acid on spinal neurones

Excitability changes induced in the striatal dopamine-containing terminals following frontal cortex stimulation

The excitability of the dopamine-containing terminal field in the striatum (St) following frontal cortex (FC) stimulation was investigated in halothane-anesthetized rats. Either glutamic acid (GLU, 6.2 mM) or square pulses (a train of 25 pulses, 500-800 microA/0.3 ms: 1 Hz/20 s) were used to stimulate FC. To stimulate St monophasic square wave pulses (10-4000 microA/0.5 ms/1 Hz) were delivered. Excitability was measured by determining the threshold for antidromic activation of substantia nigra cells. Threshold was defined as the minimum current required for antidromic invasion of the cell on 100% of non-collision trials. The mean threshold current was 1029 +/- 167 microA. Following FC stimulation a significant decrease (30%) in excitability was observed in most cases (80%). No correlation between firing rate and threshold fluctuations was observed. It is concluded that FC activity decreases the excitability of the dopaminergic nigrostriatal terminal field. Whether this is a direct or an indirect effect is discussed.

Effect of calcium ions on the sensitivities of cultured cerebellar neurons to glutamate and aspartate

Iontophoretically applied glutamate and aspartate induced depolarizations in immature (6-13 days in culture) and mature (25-45 days) cultured chick cerebellar neurons, immature neurons being less sensitive. The input resistances of the neurons were variously changed by these amino acids. Reversal potentials of the depolarizations induced by both amino acids were similar in either immature or mature neurons. The population of amino acid-sensitive neurons increased with maturation. In mature neurons, the amplitude of glutamate- or aspartate-induced depolarization was decreased by addition of 10 mM Ca2+ to normal Tyrode's solution, aspartate responses being decreased more greatly. In low-Na+ solution (2.7 mM), however, high Ca2+ significantly enhanced amino acid-induced depolarizations. In immature neurons, on the other hand, the amplitude of glutamate- or aspartate-induced depolarization was drastically and consistently increased when 10 mM Ca2+ was added either to normal solution or to the low-Na+ solution. These enhancing actions of Ca2+ were abolished by Mn2+, but only partially by 10 mM glutamic acid diethylester or 1 mM D-alpha-aminoadipate, though responses to both amino acids in normal solution were blocked by these antagonists at the same concentrations. These results suggest that calcium ions enhance the effect of glutamate and aspartate in immature neurons, possibly by interacting with the ionophores involved in amino acid responses.

"Desensitization" of excitatory amino acid responses in the rat olfactory cortex

Repeated application of the excitatory amino acid transmitter candidates, L-aspartate and L-glutamate and of N-methyl-D-aspartate, kainate and quisqualate to slices of olfactory cortex evoked progressively smaller depolarizations. These "desensitizations" were concentration-dependent, essentially irreversible and non-selective, although responses to gamma-aminobutyric acid (GABA) and to potassium ions were not significantly depressed. The specific N-methyl-D-aspartate receptor antagonist 2-amino-5-phosphonopentanoic acid, partially blocked the reduction in responses to amino acids which accompanied "desensitization" by N-methyl-D-aspartate, suggesting that activation of receptors is an obligatory step in provoking the phenomenon. "Desensitization" of responses was not prevented by the lectin concanavalin A but was potentiated by ouabain, an inhibitor of the sodium-potassium pump. It is proposed that the phenomenon does not reflect a true desensitization of receptors but is possibly the result of accumulation of intracellular sodium because of overloading the sodium pump. Under circumstances where responses to N-methyl-D-aspartate, quisqualate and kainate were "desensitized" by approx. 96%, depolarizations evoked by L-aspartate and L-glutamate were reduced by only 55%: these residual responses were not antagonized by the excitatory amino acid receptor blockers, (+/-)cis-2,3-piperidine dicarboxylate and 2-amino-4-phosphonobutyrate or by dihydrokainate, an inhibitor of the uptake of glutamate and aspartate. One possibility is that the residual responses reflect an interaction between L-aspartate and L-glutamate and an as yet unknown category of receptors.

Involvement of neuronal cell bodies of the mesencephalic locomotor region in the initiation of locomotor activity of freely behaving rats

The locomotor activity of freely-moving rats was increased substantially by injections of L-sodium glutamate or of picrotoxin, a GABA antagonist, into the region of the tegmental pedunculopontine nucleus. The onset of hyper-motility was more rapid with L-glutamate than with picrotoxin and the duration shorter. Locomotor activity from injecting amphetamine unilaterally into the nucleus accumbens was reduced by injections of GABA into the ipsilateral pedunculopontine nucleus. These observations provide additional evidence implicating neurons of the MLR and possibly GABA synaptic inputs to these neurons in locomotor activity and suggest that they may mediate indirect inputs from the nucleus accumbens.

Characterization of coeruleospinal inhibition of the nociceptive tail-flick reflex in the rat: mediation by spinal alpha 2-adrenoceptors

Several lines of evidence implicate bulbospinal noradrenergic pathways in antinociception and descending inhibition. In the present study, descending inhibition of the nociceptive tail-flick (TF) reflex by electrical stimulation in the dorsolateral pons (DLP) and the spinal neurotransmitter(s) mediating that inhibition were characterized in lightly pentobarbital-anesthetized rats. It was determined that 10 s of stimulation in the DLP prior to the application of heat to the tail resulted in optimum (lowest) thresholds for inhibition of the TF reflex. Conditioning-test studies indicated that the duration of the inhibitory effects produced by stimulation outlasted the 10-s period of stimulation by approximately 5 s. Systematic mapping studies revealed that inhibition of the TF reflex could be produced by stimulation throughout a large portion of the DLP; however, stimulation sites requiring the lowest intensities of stimulation (less than or equal to 25 microA) were in the locus coeruleus/subcoeruleus. Changes in blood pressure were not produced at this intensity and duration of stimulation. S-glutamate microinjections and stimulation strength-duration determinations suggest that inhibition of the TF reflex produced by stimulation in the locus coeruleus/subcoeruleus results from activation of cell bodies. The intrathecal administration of pharmacologic antagonists (phentolamine, yohimbine, prazosin, naloxone, methysergide, atropine and bicuculline) revealed that only the alpha-adrenergic antagonists phentolamine and yohimbine resulted in significant increases in stimulation thresholds in the locus coeruleus/subcoeruleus for inhibition of the TF reflex (83.1 and 93.9%, respectively). These results indicate that inhibition of the spinal nociceptive TF reflex produced by electrical stimulation in the locus coeruleus/subcoeruleus is at least in part a noradrenergic, postsynaptic alpha 2-adrenoceptor-mediated effect.

Chemical stimulation of the area postrema induces cardiorespiratory changes in the cat

The purpose of our study was to determine the cardiorespiratory effects of exciting cell bodies of the area postrema of the cat. This was accomplished by local application of L-glutamic acid (bilateral application of 5 microliter of a 250-1000 mM solution) and kainic acid (bilateral application of 5 microliter of a 40 mM solution) to the area postrema of chloralose-anesthetized cats while monitoring arterial pressure, heart rate, tidal volume and respiratory rate. These excitatory amino acids activate neuronal cell bodies but not axons of passage. L-Glutamic acid produced a dose-dependent increase in arterial pressure, decreases in respiratory rate and minute volume and, occasionally, ventricular tachyarrhythmias. Kainic acid produced effects similar to those seen with L-glutamic acid except the changes in respiratory activity were more pronounced with each animal exhibiting respiratory arrest. In artificially respired animals, kainic acid produced similar cardiovascular changes as those occurring in spontaneously breathing animals (i.e. increases in arterial pressure of 61 +/- 5.7 mm Hg, and in heart rate of 32 +/- 8.3 beats/min). Finally, application of kainic acid to the area postrema abolished the pressor and tachycardic responses to bilateral occlusion of the carotid arteries. These results suggest that activation of cell bodies in the area postrema can result in pronounced cardiorespiratory changes.

The variation in action of excitatory amino acids in relation to distance of iontophoretic application to spinal motoneurones

Intracellular recordings were made from lumbosacral motoneurones of barbiturate-anaesthetized cats. DL-homocysteate (DLH) and L-glutamate were iontophoresed extracellularly over a range of distances from the impaled motoneurone. Movement of the iontophoretic electrode unit was controlled by a micromanipulator which was advanced independently of that moving the intracellular electrode. Depolarizations to DLH were first detected at a greater distance from the impaled motoneurones (mean, 383 micron) than depolarizations to L-glutamate (mean, 165 micron). As the point of application approached the soma of the motoneurone, depolarizations developed more rapidly, were larger and the latent period of the L-glutamate depolarization became shorter. Dendritic 'hot-spots' of the depolarizing action of L-glutamate were not detected.

Cardiorespiratory effects produced by application of L-glutamic and kainic acid to the ventral surface of the cat hindbrain

The purpose of our study was to determine the cardiorespiratory effects of exciting cell bodies at the rostral (area M), intermediate (area S), and caudal (area L) chemosensitive sites on the ventral surface of the medulla. To do this, L-glutamic and kainic acid were applied bilaterally to each chemosensitive site while monitoring tidal volume (VT), respiratory rate (f), mean arterial pressure (BP), and heart rate (HR) in chloralose-anesthetized cats. Application of solutions (5 microliter) of L-glutamic acid ranging from 62.5 to 2000 mM to the intermediate area produced concentration-dependent increases in VT (from 2.0 +/- 0.6 ml to 14 +/- 1.1 ml) and BP (from 2.0 +/- 1.7 mm Hg to 39 +/- 5.3 mm Hg). No significant changes in f and HR were noted. Similar effects were observed with application of kainic acid. Application of L-glutamic acid to the caudal area produced hypotension (-24 +/- 5.4 mm Hg) with no accompanying changes in VT and f. No responses were observed after application of L-glutamic acid to the rostral area. These data suggest that activation of cell bodies on the intermediate area produces simultaneous stimulatory effects on BP and VT, whereas activation of cell bodies at the caudal area produces selective depressant effects on BP.

Retrograde labeling of dorsal root ganglion neurons after injection of tritiated amino acids in the spinal cord of rats and cats

The present experiments are based upon evidence that neurons may selectively take up at their terminals, and retrogradely transport, the same chemical they use as a neurotransmitter or its analogues. In an attempt to identify dorsal root ganglion (DRG) neurons that use glutamic acid as a neurotransmitter, [3H]D-aspartate ([3H]D-Asp) was chosen as a marker, since it is a metabolically inert amino acid known to be taken up by the same affinity mechanism as L-aspartate and L-glutamate. Adult rats and cats received injections of 50 nl to 1.5 microliter of [3H]D-Asp (500 microCi/microliter) in the dorsal horn of cervical segments (C3 to C6). At 9 to 48 hr after injection, all animals were perfused with 5% glutaraldehyde. After sections were processed for autoradiography, the DRG neurons situated most closely to the injection site were chosen from representative cases, and the number and cross-sectional area of labeled and unlabeled perikarya with a nucleolus in the plane of the section were calculated. In rats, about 4% of the sampled DRG neurons were autoradiographically labeled, and the mean perikaryal area of these neurons was about twice that of unlabeled perikarya. In cats, the percentage of labeled perikarya ranged between 6.5% and 13.27% of the sampled population. The ratio of the mean perikaryal area of labeled neurons to that of unlabeled neurons ranged between 1.6 and 2.5. In a control cat injected with [3H]proline at C7, all perikarya in the C7 DRG were autoradiographically labeled. However, with injection of [3H]gamma-aminobutyric acid ([3H]GABA) selective retrograde labeling was observed. Quantitative data in rat showed that perikarya labeled at the C6 level after injection of this amino acid constituted about 8% of the sample population in C6 DRG. The ratio of the size of labeled to unlabeled perikarya was 2.02. In one cat injected with [3H]GABA at caudal C3, the largest number of labeled perikarya were in C4 DRG and comprised up to 5.32% of the sampled population. The ratio of the size of labeled to unlabeled perikarya was 1.57. The results in cases of injection with [3H]D-Asp may be interpreted as consistent with the idea that a fraction of DRG neurons use glutamate and/or aspartate as neurotransmitter(s).(ABSTRACT TRUNCATED AT 400 WORDS)

Arginine-vasopressin enhances the responses of lateral septal neurons in the rat to excitatory amino acids and fimbria-fornix stimuli

In the present study we investigated the effect of arginine-vasopressin (AVP) on responses induced in lateral septal neurons of the rat by iontophoretically administered excitatory and inhibitory amino acids and by synaptical stimuli delivered through fimbria-fornix (fi-fx) fibers. In the majority of the lateral septal neurons, iontophoretically applied AVP induced a marked increase in the excitatory responses to glutamate, aspartate, quisqualate and N-methyl-D-aspartate. The responses to excitatory amino acids frequently remained elevated several minutes after termination of the peptide administration. Inhibitory responses induced by GABA were not affected by AVP. The responsiveness of lateral septal single units to fi-fx stimuli was enhanced during iontophoretic administration of AVP. The enhanced responsiveness also appeared from experiments in which topically applied AVP induced a prolonged increase in the negative but not the positive wave of field potentials evoked in the lateral by fi-fx stimuli. The possible physiological significance of these findings is discussed.

Action of intrathecal capsaicin and its structural analogues on the content and release of spinal substance P: selectivity of action and relationship to analgesia

Intrathecal injections of capsaicin (CAP) and 4 other homovanillic acid (HMV) derivatives related to the structure of CAP were carried out. Capsaicin, 1-nonenoylvanillylamide (NVA), HMV-dodecylamide (DCA) (but not HMV-cyclohexylamide (CHA) or HMV-hexadecylamide (HDC] reduced the spinal content of substance P (SP), as measured by radioimmunoassay (RIA), and increased the tail-flick latency. Similar injection of kainic acid and piperine reduced levels of SP but failed to affect the tail-flick latency. None of the agents used affected spinal levels of cholecystokinin (CCK) or vasoactive intestinal peptide (VIP) as measured by RIA. In experiments using in vivo superfusion of the rat spinal cord, CAP, DCA and NVA were found to stimulate release of SP. Capsaicin had no effect on the levels of CCK or VIP immunoreactivity in the spinal superfusate. A tachyphylaxis to the effect of CAP and DCA on spinal SP release was demonstrated. Pretreatment with either agent blocked the releasing effect of the second. Pretreatment with an inactive analogue (HDC) had no effect on the subsequent activity of CAP. Kainic acid and piperine did not induce release of SP from the spinal cord. The relative selectivity of spinally administered capsaicinoids with regard to their effects on the content and release of peptides known to be contained in primary afferents and the presence of a similar structure-activity relationship for depletion and release of SP, desensitization and antinociception suggest the presence of a specific receptor site associated with a specific population of primary afferents through which pain information may pass. Whether SP is an 'afferent pain transmitter' is not clear, but at the least, it appears to serve as a marker for a population of afferents acted upon by spinally administered capsaicinoids.

The reversal potential of excitatory amino acid action on granule cells of the rat dentate gyrus

The responses of granule cells to glutamate, aspartate, N-methyl-D-aspartate (NMDA), quisqualate and kainate applied by ionophoresis on to their dendrites in the middle molecular layer of the dentate gyrus were studied with intracellular electrodes using an in vitro hippocampal slice preparation. On passive depolarization 75% of the granule cells displayed anomalous rectification, which persisted in the presence of TTX and TEA but was eliminated by Co2+ or the intracellular injection of Cs+. Short ionophoretic applications of all the excitatory amino acids evoked dose-dependent depolarizations that were highly localized: movement of the ionophoretic electrode by as little as 10 microns could substantially change the size of the response. The depolarizations evoked by glutamate, asparatate, quisqualate and kainate were unaffected by TTX and Co2+. The depolarization evoked by NMDA was unaffected by TTX but markedly reduced by Co2+. Following intracellular injection of Cs+, neurones could be depolarized to +30 mV and the depolarizations produced by glutamate, quisqualate, NMDA and kainate reversed. The reversal potentials (E) were Eglutamate: -5.6 +/- 0.4 mV; ENMDA: 1.8 +/- 1.9 mV; Equisqualate: -3.9 +/- 1.9 mV; Ekainate: -4.6 +/- 2.0 mV. The excitatory post-synaptic potential (e.p.s.p.) evoked by stimulation of the medial perforant path could also be reversed and Ee.p.s.p. was -5.5 +/- 1.1 mV. The 6 mV difference between ENMDA and the equilibrium potential for the other exogenously applied excitatory amino acids and the statistically significant difference between ENMDA and Ee.p.s.p. (P less than 0.005; d.f.: 7) is consistent with our earlier hypothesis that both the transmitter released by the medial perforant path and exogenously applied glutamate are unlikely to interact with NMDA receptors.

Amino acid neurotransmission between fimbria-fornix fibers and neurons in the lateral septum of the rat: a microiontophoretic study

We investigated the nature of the excitatory amino acid and the type of amino acid receptor involved in the projection of fimbria-fornix (fi-fx) fibers on neurons in the lateral septal complex (LSC) of the rat. It appeared that neurons which were strongly orthodromically activated (SOA) by stimulation of fi-fx fibers were excited by glutamate (GLU) and aspartate (ASP) at much lower ejecting currents than neurons which were only weakly orthodromically excited. In addition, GLU was a stronger agent than ASP, particularly in SOA septal cells. Two amino acid antagonists tested, glutamic acid diethylester (GDEE) and 2-amino-5-phosphonovaleric acid (2-APV), selectively antagonized responses to the amino acid agonists quisqualate (QUIS) and N-methyl-D-aspartate (NMDA), respectively. They also depressed GLU- and ASP-induced responses, although in that case the antagonists frequently had to be expelled with currents higher than those needed to block QUIS- and NMDA-evoked excitations. Furthermore, GDEE frequently antagonized GLU-induced responses better than ASP-evoked excitations, whereas 2-APV often blocked responses to ASP more effectively than those to GLU. It was observed that GDEE, ejected with currents that blocked responses to QUIS reversibly, decreased the number of synaptic responses induced in SOA cells by fi-fx stimuli. Synaptically induced excitation in these neurons was consistently unaffected by 2-APV, even when the antagonist was expelled with high currents. According to these results, LSC neurons, in particular the SOA neurons, are more readily activated by GLU than by ASP. Monosynaptic excitations elicited in SOA septal cells by fi-fx stimuli appear to be predominantly if not exclusively mediated by QUIS receptors. There are indications that GLU-induced responses in the LSC neurons are presumably mediated by the QUIS receptors. From these data it may be inferred that GLU rather than ASP is the transmitter involved in the projection of fi-fx fibers on LSC neurons.

Responses of solitary retinal horizontal cells from Carassius auratus to L-glutamate and related amino acids

Effects of L-glutamate and its analogues on membrane potentials of solitary horizontal cells were studied by intracellular recording. L-glutamate depolarized these cells at micromolar concentrations (greater than or equal to 10 microM), while D-glutamate and L-alpha-amino adipic acid produced slight depolarizations only at millimolar concentrations. Neither L- nor D-aspartate, even at millimolar doses, produced any change in solitary horizontal-cell resting potential. Solitary horizontal-cell responses to L-glutamate did not desensitize detectably. Responses to pairs of brief, ionophoretic pulses of L-glutamate were nearly equal in amplitude at inter-pulse intervals as short as 50 ms. Responses to maintained applications of low doses of L-glutamate did not decline for as long as 2 min. Depolarizing responses were produced by ionophoretic applications of L-glutamate near cell somata as well as dendrites. The mean sensitivity was 1.4 +/- 1.5 mV/nC with a maximum of 5.1 mV/nC. Depolarizing responses to L-glutamate reversed in polarity at membrane potentials between 0 and -20 mV, were accompanied by a decrease in membrane slope resistance, and were suppressed by replacement of extracellular sodium ions with choline. These results demonstrate that chemosensitivity of retinal horizontal cells to acidic amino acids persists after dissociation protocols, and in several respects resembles that found in horizontal cells in situ. These findings are consistent with the notion that retinal horizontal cells receive a synaptic input involving L-glutamate or a similar substance.

Ionic mechanism of a hyperpolarizing glutamate effect on two identified neurons in the buccal ganglion of Aplysia

The ionic mechanism of a membrane effect of L-glutamate on two identified neurons in the buccal ganglion of Aplysia kurodai was investigated with conventional microelectrode techniques and glutamate iontophoresis. Bath-applied and iontophoresed glutamate hyperpolarized the membrane and increased the membrane conductance. The hyperpolarizing glutamate response decreased in amplitude and finally reversed its polarity by conditioning hyperpolarization. The reversal potential of the hyperpolarizing glutamate response was close to the ECl (-60 mV). The reversal potential changed by 22.4 mV when the external chloride concentration was altered by a factor of 5. The relationship between the iontophoretically applied current and the membrane conductance changes was suggestive of two glutamate molecules reacting with a single receptor site. The hyperpolarizing glutamate response was essentially unaffected by 2-amino-4-phosphonobutyric acid (2-APB), L-proline, and quinuclidinyl benzilate (QNB). It was concluded that the hyperpolarizing glutamate response was generated by an activation of Cl- conductance.

Inhibition of thalamic ventrobasal complex neurons by glutamate infusion into the thalamic reticular nucleus in rats

In urethane-anesthetized rats a 0.36-mm metallic cannula for infusion was positioned in the somatosensory component of the thalamic reticular nucleus (sTR), where movement of the vibrissae evoked neuronal discharge. Infusion there of 0.125-0.5 microliter of a 50 mM solution of glutamate over a 1-min period suppressed both spontaneous and evoked discharge of neurons in the ventrobasal complex (VB), but only for those which also responded to vibrissal stimulation. VB neurons activated by somatosensory stimuli at other locations were unaffected. Thus, excitation of neurons in sTR inhibits those in VB, but the effect appears to be highly coordinated somatotopically.

Responses of substantia gelatinosa neurons to putative neurotransmitters in an in vitro preparation of the adult rat spinal cord

Extracellular recordings were performed from neurons of the substantia gelatinosa (SG) in an in vitro preparation obtained from the spinal cord of adult rats. About 40% of neurons were spontaneously active. They could be synaptically influenced by low and high threshold fiber input entering the spinal cord through dorsal and ventral roots. Repetitive low threshold stimulation led to a transient increase in activity of a number of these neurons, whereas high intensity stimulation predominantly reduced excitability. The majority of non-spontaneously active neurons responded to an increase of stimulus intensity covariantly with an increase in firing rate. The excitatory effect of phoretically administered L-glutamate as well as synaptically induced and spontaneous activity was reduced or abolished by phoretically administered GABA, glycine or the enkephalin-analogue D-Ala2-D-Leu5-enkephalin. The actions of the enkephalin analogue were blocked by phoretically applied naloxone. The findings are consistent with the notion from in vivo investigations of a structurally and functionally heterogeneous population of neurons which display a responsiveness to microtopically applied putative neurotransmitters resembling dorsal horn neurons in deeper layers.

Adrenaline synthesizing neurons in the rostral ventrolateral medulla: a possible role in tonic vasomotor control

Adrenaline-containing neurons of the rostral ventrolateral medulla (the C1 group) project selectively to autonomic spinal neurons in rats. Stimulation of these neurons electrically or chemically elevates arterial pressure, while neuronal blockade by microinjection of tetrodotoxin bilaterally drops arterial pressure to levels comparable to those produced by spinal cord transection. Adrenaline neurons of the ventral medulla appear necessary for maintaining normal levels of blood pressure, and thus may constitute a tonic vasomotor center.

Mediobasal hypothalamic neurons are excited by the iontophoretic application of sodium

In the course of studies on the responsiveness of mediobasal hypothalamic neurons to the iontophoretic application of cortisol, it was found that positive currents applied to a sodium chloride (1 M) barrel alone, but not to a choline chloride (1 M) barrel, frequently increased the firing of these neurons. Subsequently, systematic examination demonstrated that out of 102 MBH neurons 52 (51%) increased their firing by at least 30% with application of NaCl, using currents no greater than 10 nA. No such effect was obtained in response to Na application from a dilute solution (0.05 or 0.1 M). When glutamate was absent from the electrodes, the incidence of Na+ sensitivity fell to 17%, despite the routine use of backing currents to the glutamate barrel. K+ ions were more active than Na+ ions in producing excitation. When Na+ sensitivity was found, however, Na+ effects were produced by currents greater than K+ currents producing equivalent excitation. Like glutamate, K+ ions were capable of greatly enhancing responses to Na+. Comparison was made between cortisol and Na+ sensitivity in 70 MBH neurons; 28 cells responded to both, and 24 of them were inhibited by cortisol. Thus Na+ sensitivity is a frequent characteristic of MBH neurons inhibited by cortisol, and was present in 83% of cortisol-sensitive cells in this region. Iontophoresis of Na+ is commonly used as a control in pharmacological studies of the nervous system. Even more common is the case of concentrated NaCl solutions for recording. These procedures may not be as inert as previously thought, particularly in the hypothalamus.

Action of neurotensin on spinal cord neurons in the rat

Histochemical, biochemical and pharmacological data suggest that the tridecapeptide neurotensin (NT) may play a role as an intercellular messenger in the spinal cord of rats. In the present study the response of spinal cord neurons to NT was investigated employing conventional extra- and intracellular recording techniques in combination with iontophoresis or a microperfusion system which permits the control of the maximal concentration of NT reached near the neuron. Recordings were obtained from motoneurons, interneurons and from neurons in the dorsal horn receiving synaptic input from low and high threshold mechanoreceptors activated in their peripheral cutaneous receptive fields. The most commonly observed action of NT applied by either mode was an excitation after a dose-dependent delay. The response was dose-dependent, repeatable and reversible. The intracellular recordings revealed that these excitatory responses were due to a depolarizing action of NT associated with an increase in input resistance, not attributable to non-linearities in the current-voltage relationship. The present data are in agreement with most previous investigations reporting excitatory actions of NT on neurons in various neuronal structures in the peripheral and central nervous system. It seems unlikely that these excitatory effects are indirect actions mediated by an inhibition of other neurons in the vicinity.

The role of the electrogenic sodium pump in the glutamate afterhyperpolarization of frog spinal cord

Drug responses of isolated hemisected frog spinal cords were examined by means of the sucrose-gap technique. The glutamate-induced depolarizations (glu-d) of motoneurones (recorded from ventral roots), and primary afferents (recorded from dorsal roots), were followed by an afterhyperpolarization (glu-a.h.). The depolarization induced by DL-homocysteic acid (DLH) was only occasionally followed by an afterhyperpolarization (DLH-a.h.). The glu-a.h. on both roots persisted in the presence of tetrodotoxin (TTX, 0.1-1 microM), or Ringer solution containing 10 mM-Mg2+; 0.1 mM-Ca2+ or 2 mM-Mn2+; 0.2 mM-Ca2+. This indicated that the response was neither due to the release of endogenous neurally active substances nor to the activation of a Ca2+-sensitive K+ conductance. The glu-a.h. was reduced or blocked by K+-free Ringer solution, 3-acetylstrophanthin (3-Ac-Str; 1 microM) or Li+ ions, and was therefore attributed to the activity of the electrogenic Na+ pump. The duration of depolarization induced by glu or DLH was increased in the presence of K+-free Ringer solution, 1 microM 3-Ac-Str or Li ions. It is therefore suggested that the electrogenic Na+ pump may play a role in limiting the duration of depolarization induced by the action of excitatory amino acids. The re-admission of K+ ions to preparations which had been incubated in K+-free Ringer solution produced a transient hyperpolarization (K-a.h.) of the membrane potential of ventral roots which is also attributable to the activation of the electrogenic Na+ pump. Both the K-a.h. and the glu-a.h. were enhanced in Ca2+-free Ringer solution. It is therefore suggested that the Ca2+ ions may modulate the activity of the electrogenic pump in central nervous tissue.

The ionic mechanism of the excitatory action of glutamate upon the membranes of motoneurones of the frog

Simultaneous intra- and extracellular recordings with K+, Na+, Ca2+, and Cl- sensitive microelectrodes were performed in motoneurones of the spinal cord of the frog during depolarizations mediated by glutamate (GLUT) and by experimentally increased extracellular K+. Depolarization resulting from increased K+ activity (alpha K+) in the bathing solution evoked a decrease of intracellular Na+ activity (alpha Na+i); a transient increase of alpha Na+i accompanied by a decrease of alpha Na+e was observed during the depolarization induced by GLUT. Both modes of depolarization led to an increase of alpha Cl-i and a concomitant decrease of alpha Cl-e. An experimental increase of alpha K+e led to a threshold dependent increase of alpha Ca2+i by at least one order of magnitude and to an equally threshold dependent strong decrease of alpha Ca2+e. The threshold of these changes of alpha Ca2+ was at a membrane potential of -25 mV. During a depolarization of half the amplitude induced by GLUT a comparable increase of alpha Ca2+i and a smaller decrease of alpha Ca2+e were observed. The GLUT mediated changes of alpha Ca2+ were not threshold dependent and occurred synchronously with the onset of depolarization. A transient decrease of alpha K+i and a parallel strong increase of alpha K+e occurred during the GLUT induced depolarization. Depolarization evoked by an experimental increase of alpha K+e led to an increase of alpha K+i. The observed changes in the ionic composition of the intra- and extracellular fluids indicate that GLUT evokes an increase in membrane permeability to Na+ and Ca2+ and a subsequent influx of these ions into motoneurones, while the inward shift of Cl- and the outward shift of K+ are presumably passive. A voltage dependent Ca2+ influx is triggered at -25 mV membrane potential.

A method for evoking physiological responses by stimulation of cell bodies, but not axons of passage, within localized regions of the central nervous system

A method for evoking physiological responses by microinjection of sodium glutamate solution into localized regions of the central nervous system (CNS) is described. The major advantage of this method is that the cell bodies or dendritic processes of neurones within the injection site are excited, whereas axons of passage are unaffected. It was demonstrated that injections of minute volumes (50-100 nl) of 0.5 M glutamate solution into selected sites within the medulla or midbrain of anaesthetized or conscious animals, respectively, elicited marked autonomic, somatomotor or behavioural responses, depending on the injection site. In contrast, glutamate microinjection into fibre tracts failed to elicit any response, whereas electrical stimulation applied at the same sites elicited marked responses. The degree of localization of the glutamate stimulus and the relation between glutamate concentration and magnitude of evoked response are described. It is concluded that this method is a very effective means of selectively stimulating cell bodies within highly localized regions of the CNS. Further, by using this method in combination with focal electrical stimulation, it is possible in some cases to provide evidence that a response arises from excitation of axons of passage rather than cell bodies.

Role of ventrolateral medulla in vasomotor regulation: a correlative anatomical and physiological study

Two groups of experiments were carried out in rabbits. First, the ventrolateral reticular formation of the medulla oblongata was stimulated either by microinjection of sodium glutamate solution (exciting only cell bodies) or electrically (exciting cell bodies and axons). This region has been shown previously to contain a dense and compact group of bulbospinal cells. The effects of both electrical and chemical stimulation of specific sites were correlated with the density of ventrolateral bulbospinal cells at the same sites. Glutamate microinjection into the center of the group of bulbospinal cells elicited a very large and sustained increase in arterial pressure, whereas microinjection into sites outside this region elicited a very small or no response. These results suggest that it is the bulbospinal ventrolateral cells which mediate the pressor response to glutamate stimulation. Focal electrical stimulation in the ventrolateral medulla elicited increases in arterial pressure and decreases in femoral and renal vascular conductance, as well as a short-latency increase in renal sympathetic nerve activity. The most effective sites for focal electrical stimulation lay within the region of greatest density of bulbospinal cells; slightly less effective sites lay just rostral and caudal to this region. It is suggested that stimulation in these latter sites predominantly excites axons of passage. Secondly, the origin of afferent fibers to the ventrolateral vasomotor area was studied using the horseradish peroxidase (HRP) method. This revealed major projections from the medial part of the nucleus tractus solitarius and the parabrachial nucleus in the pons. The physiological and anatomical studies taken together are consistent with the hypothesis that the bulbospinal ventrolateral cells are vasomotor in function, and receive afferent inputs from brain stem nuclei which are known to play a role in autonomic regulation.

Serotonin-like actions of quipazine and CPP on spinal motoneurones

The actions of iontophoretically applied quipazine (QPZ) and 6-chloro-2-[1-piperazinyl]-pyrazine (CPP) were compared with those of serotonin (5-HT) on rat spinal motoneurones. QPZ and CPP qualitatively resembled 5-HT in that both facilitated single unit activity evoked by glutamate. Like 5-HT, the facilitation they produced could be antagonized by metergoline or methysergide. These observations are compatible with the suggestion that the actions of QPZ and CPP are mediated by 5-HT receptors. In rats pretreated with the neurotoxin 5,7-dihydroxytryptamine (5,7-DHT), QPZ and CPP remained effective in facilitating the glutamate evoked activity, whereas p-chloroamphetamine (PCA), a known releaser of 5-HT, was without effect. In contrast, PCA produced a long lasting facilitation in untreated rats. These data, taken together, suggest that QPZ and CPP are direct agonists at 5-HT receptors, but do not preclude the possibility that they might also act indirectly.

Excitatory effect of acetylcholine on different types of neurons in the first somatosensory neocortex of the rat: laminar distribution and pharmacological characteristics

In rats anaesthetized with either urethane, pentobarbital or fluothane the effects of acetylcholine, cholinergic agonists and antagonists (applied by iontophoresis) were studied on single cortical neurons of first somatosensory region. The laminar distribution of the neurons excited by acetylcholine was determined by the reconstruction of each electrode track based on a dye-deposit made at the last recording site. Neurons were identified using antidromic stimulation of the pyramidal tract, the ventrobasal thalamus and the corpus callosum. Neurons excited by acetylcholine could be segregated into two groups: one encompassing layer Vb and the upper part of layer VI, the other more deeply located at the limit between the cerebral cortex and the subjacent white matter. Neuronal responses to glutamate and nicotine, unlike those to actylcholine were evenly distributed in the cortex. Pyramidal tract neurons had corticothalamic neurons were frequently excited by acetylcholine and were shown to be located with the first group of acetylcholine sensitive neurons. Commissural neurons were rarely excited by acetylcholine and were not restricted to either group. The analysis of neuronal responses to acetylcholine and various agonists (carbachol, nicotine, acetyl-beta-methylcholine, carbamyl-beta-methylcholine, butyrylcholine) and antagonists (atropine, mecamylamine) revealed a prominent but not exclusive muscarine character. It is included (i) that cortical neurons of first somatosensory cortex which are excited by acetylcholine belong to two populations, one consisting, at least in part, of projection neurons (upper group) and the other of interneurons (lower group); (ii) that cortical acetylcholine receptors are of a 'mixed' type strongly weighted toward the muscarinic side.

Induction of 'rage' following microinjections of glutamate into midbrain but not hypothalamus of cats

Microinjections of glutamic acid were made into the same midbrain and hypothalamic sites of cats at which 'defensive-rage' behaviour was elicited by electrical stimulation. It was found that : (1) medial hypothalamic and midbrain tegmental glutamate injections were without behavioural effect; (2) midbrain periaqueductal grey injections elicited a 'rage' display. Since glutamate depolarizes cell bodies but not axons, the results suggest that there is a specific population of neurones in the midbrain whose excitation elicits this reaction.

Serotonin-induced depolarization of rat facial motoneurons in vivo: comparison with amino acid transmitters

Intracellular recordings were obtained from facial motoneurons in anesthetized rats. The effects of iontophoretically applied serotonin were compared to those of the excitatory amino acids glutamate and DL-homocysteic acid (DLH), and the inhibitory amino acids, glycine, GABA and muscimol, under various conditions of membrane polarization and intracellular chloride concentration. Iontophortically applied serotonin caused a depolarization of facial motoneurons which was accompanied by increased input resistance and increased neuronal excitability. Experiments comparing the response to serotonin with those of glycine, GABA, and muscimol demonstrated that the serotonin effect does not involve changes in membrane conductance to chloride. Comparisons of serotonin with glutamate and DLH at varying levels of membrane hyperpolarization indicated that the serotonin-induced depolarization is not caused by increased conductance to sodium or calcium, and differs in its underlying ionic mechanism from depolarizations induced by glutamate and DLH. Results were consistent with the hypothesis that serotonin causes depolarization, increased input resistance, and increased excitability in rat facial motoneurons by decreasing resting membrane conductance to potassium ions. Such changes in motoneurons in the brain stem and spinal cord probably account for some of the physiological and behavioral effects observed during pharmacological activation of serotonin receptors.

Excitatory actions of homocysteic acid on hippocampal neurons

The actions of D- and D,L-homocysteate (DH and DLH) on CA3 neurons were studied in thin sections of the guinea pig hippocampus. DH and DLH administered to the stratum radiatum induced large depolarizations in CA3 neurons. The responses to DH and DLH were accompanied by increases in membrane conductance. The amplitudes of the responses increased and decreased, respectively, during tonic hyperpolarizing and depolarizing currents. In neurons injected with Cs+, these responses were reversed in polarity at membrane potentials of -13 to -19 mV. These results indicate that receptors for homocysteate in the hippocampus have different properties from those found in the spinal cord and are quite similar to glutamate receptors.

The responses of neurones of the superficial dorsal horn to ionophoretically applied glutamate ion

Extracellular spikes were recorded from neurones in the marginal zone and substantia gelatinosa of the cat lumbar spinal cord using low-noise carbon fibre microelectrodes. Ionophoretic ejection of glutamate ion was used to distinguish soma/dendrite from axon spikes. The receptive fields of the units and their response to percutaneous electrical stimulation was investigated. The majority of units had low-threshold receptive fields on the hair and skin of the toes and foot. The receptive fields indicated a convergence of different modality afferents onto single cells. Ionophoretic glutamate acted synergistically with the action of the natural transmitter from the low-threshold afferents onto the substantia gelatinosa cells.

Effect of glutamate, aspartate and related derivatives on cerebellar purkinje cell dendrites in the rat: an in vitro study

1. The responses of Purkinje cells to short duration (pulse) ionophoretic applications of L-aspartate (L-asp), L-glutamate (L-glu), N-methyl DL-aspartate (NMDLA) and quisqualic acid in their dendritic fields were studied in vitro on sagittal slices of lobules IX and X of the adult rat cerebellum.2. Pulse application of L-asp or L-glu evoked transient and dose-dependent increases in the firing rate of the simple spikes recorded extracellularly as single units. When the ionophoretic electrode was positioned in the dendritic field of the Purkinje cells, the lowest thresholds for L-glu and L-asp mediated excitations of the cells were as low as 25 and 35 pC respectively, with a latency for maximal responses as brief as 7 ms.3. In intracellular recordings these excitatory responses consisted of depolarizations of up to 18 mV in amplitude and with depolarizing slopes up to 0.52 mV/ms. They were generally unaccompanied by changes in cell input resistance in contrast to the marked decrease which occurred in response to steady applications of large doses of L-asp and L-glu.4. The spatial distribution of the excitatory sites confirmed that the dendritic sensitivity to L-glu was greater than that of the soma and showed that the same was true for L-asp. In 34% of cells the sensitivity for L-asp declined markedly in the upper region of the molecular layer, whereas it remained high for L-glu; no such differential sensitivity was detected in the remaining 66% of cells.5. Inhibitory responses, antagonized by 10(-5) M-bicuculline in the bath, were also induced in Purkinje cells by L-glu and L-asp when the ionophoretic electrode was withdrawn from the excitatory sites by as little as 8 mum and up to 40 mum upward or downward along the track of parallel fibres or positioned as far as 250 mum laterally.6. Whenever it was applied in the molecular layer, the pulse application of NMDLA elicited no excitatory response in Purkinje cells recorded extra or intracellularly. However, slow depolarizations accompanied by a slight increase in cell input resistance were obtained with steady applications of 20-50 nA of the drug for 20-30 s.7. In contrast, pulse application of quisqualic acid appeared to have the same type of fast excitatory effect on Purkinje cells as L-asp and L-glu, but its potency was greater and its action more prolonged. Furthermore, its steady application led to an abrupt and marked decrease in cell membrane resistance.8. The excitatory effects of L-asp, L-glu and quisqualic acid were antagonized by L-glutamic acid diethyl ester more consistently than by D-alpha-aminoadipate, suggesting together with previous observations that L-asp and L-glu act on Purkinje cells via quisqualic acid rather than via NMDLA receptors.

Excitation of hippocampal pyramidal cells by glutamate in the guinea-pig and rat

1. The mechanism by which L-glutamic acid depolarizes hippocampal CA1 pyramidal neurones was investigated by using the in vitro slice and ionophoretic techniques. 2. Two types of responses were seen. One (in 85% of cells) consisted of spike discharges that outlasted the glutamate-induced depolarization. In the other (the rest of the cells), spikes were produced only during the rising phase of the depolarization. 3. The effect was highly localized; it disappeared when the ionophoretic electrode was moved vertically by as little as 20 micrometers. 4. The effect of glutamate persisted after synaptic transmission was blocked; this probably was due to a direct effect of glutamate on the cell membrane. 5. Small doses of glutamate produced either no change or an apparent increase in input resistance. With larger doses, the input resistance invariably decreased. The apparent increase in input resistance was not seen in cells treated with Mn2+ and TTX and is believed to be an effect of the depolarization rather than a direct effect of glutamate. 6. By extrapolation, the reversal potential for the glutamate response (EGlu) was found to -3.6 mV. 7. Following intracellular injection of Cs+, neurones could be depolarized to a range of +20 to +50 mV. The glutamate response could then be reversed. EGlu in these cells was -1.5 mV. 8. Using the Cs+-injection technique, it was also possible to reverse the e.p.s.p. E.e.p.s.p. was similar to EGlu. 9. When the external sodium concentration was reduced, the size of the glutamate response decreased, and EGlu became more negative.

Immediate behavioral effects of kainic acid injections into the midbrain reticular core

Microinjections of kainic acid into the midbrain reticular core were performed in chronically implanted, unanesthetized cats. The immediate effects of kainate excitation were studied during the first 8 h, in animals without any behavioral or EEG signs of epilepsy. Animals displayed pupillary dilatation, piloerection, accelerated respiration, a frozen attitude with a complete lack of facial expression, and no or only very slight orienting reactions. The most structural syndrome was a hallucinatory-type behavior that began in the first hour following the injection. Animals moved forward in a crouched position as if stalking a prey, vocalizing and opening their mouth in an attacking attitude, or moved back as if defending themselves against as imaginary menacer, seeming virtually terrified. The EEG desynchronization began 20-30 sec after the onset of injection and lasted for 12-14 h without any trace of alpha rhythm, spindles or slow waves. Control injections of buffer solution into the midbrain core and kainic acid in other cerebral structures were followed neither by the hallucinatory defense-attack syndrome, nor by comparably long-lasting EEG desynchronization. The hallucinatory-type behavior elicited during the waking state in the present experiments is compared to the oneiric behavior described by Jouvet and Delorme [21] during paradoxical sleep in animals with suppression of muscular atonia, and possible common mechanisms are discussed.

The stimulation of ion fluxes in brain slices by glutamate and other excitatory amino acids

The stimulation of ion movements by excitatory amino acids in brain slices allows the study of various events related to the process of excitatory neurotransmission. Presynaptic mechanisms of uptake of putative neurotransmitters can be followed by the influx of Na+ ions. Postsynaptic depolarizations due to the activation of action potentials or of ionophores associated with specific receptors can be monitored by measurements of the rate of efflux of radioactive tracer ions. Thus, the pharmacological properties of the excitatory amino acid receptors can be investigated as well as those of their putative endogenous effectors.

Multiple reversal potentials for responses to L-glutamic acid

Reversal potentials for L-glutamic and kainic acid were determined from foetal mouse neurones, grown dissociated in culture, and originating either from the brain or spinal cord. Amino acids were applied at known concentrations by pressure microperfusion and responses recorded using conventional intracellular techniques. Altering membranes potential by injecting current through the recording electrode permitted direct (not extrapolated) observation of reversal potentials. Values of reversal potentials differed from previous reports in culture but were still well below those predicted solely from an increase in sodium conductance. Furthermore, with some neurones it was possible to demonstrate multiple phases of response, each phase differing in time course and possessing a separate reversal potential. One reversal potential indicated the participation of potassium conductance in the response.

Distinct pharmacological properties of excitatory amino acid receptors in the rat striatum: study by Na+ efflux assay

Specific 22Na+ efflux rates from preloaded rat striatal slices are increased in a dose-dependent manner by L-glutamate and other excitatory amino acids displaying the following order of efficiency: N-methyl-D-aspartate greater than DL-homocysteate greater than quisqualate greater than kainate greater than D-glutamate greater than L-glutamate greater than L-aspartate. Amino acid antagonists such as 2-amino-5-phosphonovalerate, gamma-D-glutamylglycine, DL-aminosuberate, DL-aminoadipate, and diethyl glutamate but not nonexcitatory amino acids such as gamma-aminobutyric acid inhibit the amino acid-induced increase in specific 22Na+ efflux rate. Increased K+ concentrations, in the presence of 2 mM Ca2+, increase the specific 22Na+ efflux. The latter and the response to N-methyl-D-aspartate, but not the responses to L-glutamate, L-aspartate, quisqualate, and kainate, are inhibited to similar extents by the same antagonists. These results suggest the release from striatal nerve terminals of a putative neurotransmitter with pharmacological properties different from those of L-glutamate or L-aspartate but similar to those of N-methyl-D-aspartate. The results of this study show that the stimulation of the 22Na+ efflux in brain slices by neuroactive amino acids and K+ ions is a valid and powerful tool for pharmacological investigations of excitatory amino acid receptors and their putative ligands.