Antinociceptive effects of intrathecal taurine and calcium in the mouse.

Taurine (Tau), calcium (Ca+2) and opiates each produce antinociception when injected i.t. in mice. This study was initiated to determine whether there is a common mechanism underlying their antinociceptive effects. Using the abdominal stretch assay, the antinociceptive effects of both Tau (12 nmol) and Ca+2 (72 nmol) were antagonized by i.t. TAG (4.4 nmol), a Tau antagonist, but not by i.p. injection of the opiate antagonist naloxone (5 mg/kg). The antinociceptive effects of Tau and Ca+2 correlated with their ability to inhibit the intensity of caudally-directed biting and scratching behaviors produced by i.t. NMDA or kainic acid. The inhibitory effects of both Tau and Ca+2 on the biting and scratching behaviors behaviors induced by substance P or excitatory amino acids were reversed by TAG, suggesting a common mediation by Tau. These data indicate that the antinociceptive effects of both Tau and Ca+2 appear to be mediated, at least in part, by Tau but not by the release of endogenous opioid compounds. In addition, inhibition of chemical irritant-induced nociception may be produced by a simple blockade of excitatory amino acid activity.

Changes in extracellular concentrations of glutamate, aspartate, glycine, dopamine, serotonin, and dopamine metabolites after transient global ischemia in the rabbit brain.

Although considerable evidence supports a role for excitatory amino acids in the pathogenesis of ischemic neuronal injury, few in vivo studies have examined the effect of increasing durations of ischemia on the extracellular concentrations of these agents. Recently, other neurotransmitters (e.g., glycine and dopamine) have been implicated in the mechanism of ischemic neuronal injury. Accordingly, this study was undertaken to examine the patterns of changes of extracellular glutamate, aspartate, glycine concentrations in the hippocampus, and dopamine, serotonin, and dopamine metabolites in the caudate nucleus with varying durations (5, 10, or 15 minutes) of transient global cerebral ischemia as evidence to support their pathogenetic roles. Microdialysis was used to sample the brain's extracellular space before, during, and after the ischemic period. Glutamate and aspartate concentrations in the dialysate increased from baseline by 1-, 5-, and 13-fold and by 4-, 9-, and 31-fold, respectively, for the three ischemic durations. The concentrations returned to baseline rapidly after reperfusion. The peak concentrations of glutamate and aspartate were significantly higher with increasing ischemic duration. Dopamine concentrations increased by approximately 700-fold in response to all three ischemic durations and returned to baseline within 10 min of reperfusion. Glycine, in contrast, increased during ischemia by a mean of 4-fold, but remained elevated throughout the 80-min period of reperfusion. The final concentrations of glycine were significantly higher than baseline levels (p = 0.0002, Mann-Whitney test). That glutamate and aspartate concentrations in the hippocampus co-vary with the duration of global ischemia is taken as supportive evidence of their pathogenetic role in ischemic neuronal injury.(ABSTRACT TRUNCATED AT 250 WORDS)

Hypothermia prevents ischemia-induced increases in hippocampal glycine concentrations in rabbits.

We subjected 10 New Zealand White rabbits to 10 minutes of global cerebral ischemia under either normothermic (37 degrees C) or moderately hypothermic (29 degrees C) conditions. Hippocampal concentrations of glutamate, aspartate, and glycine were monitored using in vivo microdialysis. Outcome was assessed by both neurological and neuropathologic criteria. Hypothermia afforded nearly complete protection from ischemic injury. Ischemia-induced increases in the concentrations of glutamate, aspartate, and glycine in the normothermic group (3, 12, and 3 times baseline) were strikingly attenuated in the hypothermic group. In addition, the prolonged postischemic elevation of glycine levels seen in the normothermic group was absent in the hypothermic group. These results suggest that the neuroprotective properties of hypothermia may reside, in part, in their ability to prevent increases in the extracellular concentrations of amino acids that enhance the activity of the N-methyl-D-aspartate receptor complex.

NMDA-, kainate- and quisqualate-stimulated release of taurine from electrophysiologically monitored rat hippocampal slices.

While excitatory amino acids (EAAs) are known to evoke the release of taurine in the hippocampus, we have found that taurine is localized primarily in dendrites and only to a lesser extent in terminals in this region. To determine whether taurine is released as a neurotransmitter by non-toxic concentrations of EAAs, or exclusively as a neuroprotectant in response to excitotoxicity, we monitored the release of amino acids from hippocampal slices during simultaneous electrophysiological recording in the CA1 region to assess tissue viability. N-methyl-D-aspartate (NMDA) was the most potent of the EAA agonists tested for stimulating release of taurine. Exposure of slices to 120 microM NMDA increased the concentration of taurine in the perfusate to 1325% of its basal value. Kainate (KA) at a concentration of 128 microM increased taurine to 543% of baseline while quisqualate (Quis) at a concentration of 120 microM increase taurine to only 202% of its baseline value. Release of taurine in response to NMDA and KA peaked during the period when the concentration of the agonist was declining in the bath and did not return to its baseline value until 20 min after removal of the agonist. Increases in release of taurine were associated with concentrations of NMDA, KA, and Quis that caused an incomplete recovery of the CA1 field potential. These results suggest that taurine is primarily released by concentrations of glutamate receptor agonists that exhibit evidence of excitotoxicity in the CA1 region.

Excitatory amino acids are released from rat primary afferent neurons in vitro.

Multiple lines of evidence implicate the excitatory amino acids (EAAs) (L-aspartate (L-Asp) and L-glutamate (L-Glu) as excitatory transmitters in the spinal cord. The specific objective of this study was to determine whether the EAAs are released from primary afferents. Dorsal root ganglia (DRG) from 2 to 18-day-old rats dissected and cultured for 1-2 weeks were washed in modified Ringers recording solution for a period of 1 h to allow equilibration. The mean +/- S.E.M. baseline concentrations of EAAs recovered during a 5 min interval were 533.29 +/- 65.59 nmol for L-Glu and 106.67 +/- 14.05 nmol for L-Asp. Stimulation of DRG organotypic cultures with potassium resulted in a significant concentration-dependent increase in the release of both EAAs. The concentration of Asp increased to 166 +/- 17% and 203 +/- 13% in response to 5 min exposure of the culture to 25 and 50 mM potassium, respectively. The concentration of Glu increased to 155 +/- 12% and 226 +/- 18% of control in response to the same stimuli. In response to application of 50 mM potassium for 25 min, peak concentrations increased to 465 +/- 53% for Asp and 312 +/- 51% for Glu of the basal concentration. Exposure of the cultures to 1 or 10 microM capsaicin also caused release of both EAAs. The concentrations of Asp and Glu significantly increased to 204 +/- 11% and 165 +/- 15% of basal concentrations, respectively, in response to a 5 min exposure to 1 microM capsaicin. High [K+]e failed to increase the release of EAAs from cultures where DRG cell bodies were removed 72 h prior to release experiments. These results confirm results demonstrating release of EAA from mammalian spinal cord tissues and directly demonstrate for the first time that primary afferent fibers are specifically involved in this release.

Differential effects of C- and N-terminal substance P metabolites on the release of amino acid neurotransmitters from the spinal cord: potential role in nociception.

Extensive evidence implicates Substance P [SP(1-11)] as a primary afferent neurotransmitter or modulator of nociceptive information, and there is increasing evidence that the excitatory amino acids aspartate (Asp) and glutamate (Glu) may also act as nociceptive neurotransmitters. We have previously demonstrated that nociceptive stimulation (metatarsal injection of formalin) caused a tetrodotoxin (TTX)-sensitive release of Asp and a TTX-insensitive release of Glu from the dorsal spinal cord. We have also shown release of Asp and Glu following the direct infusion of SP(1-11), suggesting that formalin-induced Asp or Glu changes could be secondary to an initial release of SP(1-11). In contrast to nociception, pretreatment with TTX, reported here, had no effect on the SP(1-11)-induced release of Asp, suggesting a presynaptic mechanism. Behavioral experiments, in both our laboratory, and others, now suggest that the N-terminal products of SP metabolism play a distinct role in the modulation of SP(1-11) nociception, possibly through an interaction with an opiate receptor. To test the hypothesis that N- and C-terminal fragments of SP produce opposite effects on biochemical events potentially involved in nociception, we compared the effects of infusion of the N-terminal metabolite SP(1-7) and the C-terminal metabolite SP(5-11) on changes in the ECF concentration of amino acids in the spinal cord as a measure of their apparent release, using microdialysis. Intradiaylsate infusion of SP(5-11) increased the release of Asp, Glu, asparagine (Asn), glycine (Gly), and taurine (Tau). The changes in Asp, Glu, and Tau were similar in direction and magnitude to changes produced by SP(1-11) or formalin injection, further supporting the hypothesis that the C-terminal is responsible for the nociceptive effects of SP(1-11). In contrast, infusion of SP(1-7) significantly decreased the release of Asn, Tau, Glu, and Gly. This inhibition of amino acid release is consistent with the hypothesis that N-terminal metabolites produce opposite effects to those of C-terminal metabolites of SP(1-11). The decreases in Glu, Asn, Gly, and Tau following SP(1-7) infusion were significantly reduced by i.p. or intradialysate naloxone. Systemic naloxone had no significant effects on the SP(5-11)-induced amino acid changes; however, it did inhibit the SP(1-11)-induced increase in Asp and Glu. Intradialysate naloxone had no effect on the SP(1-11)-induced increases.(ABSTRACT TRUNCATED AT 400 WORDS)

Extracellular amino acid concentrations in the dorsal spinal cord of freely moving rats following veratridine and nociceptive stimulation.

In vivo microdialysis was used to sample extracellular concentrations of amino acids in the dorsal lumbar spinal cord of freely moving rats. Changes in the extracellular concentrations of amino acids were measured in response to infusion of veratridine (180 microM), a sodium channel activator, as well as during acute noxious stimulation by an injection of 5% formalin into the metatarsal region of the hindleg. Veratridine produced a tetrodotoxin (TTX)-sensitive increase in the extracellular concentration of Glu. Concentrations of Asp, taurine, Ala, Asn, and Gly were not significantly elevated following veratridine stimulation. Intradermal injection of formalin produced a TTX-sensitive increase in Asp concentration and a non-TTX-sensitive increase in Glu concentration. These data support the hypothesis that Glu and Asp are dorsal horn neurotransmitters involved in nociception.

NADP-specific glutamate dehydrogenase in Metridium senile (L.).

1. An NADP-specific glutamate dehydrogenase (E.C. 1.4.1.4) of mitochondrial origin has been detected in M. senile, a sea anemone. 2. Substrate specificity and starch gel electrophoresis experiments indicated an absence of the NAD(P) glutamate dehydrogenase (E.C. 1.4.1.3). 3. This NADP specific GDH activity appears to be the sole GDH activity in species of the animal phylum Coelenterata.