Stimulation of metabotropic but not ionotropic glutamatergic receptors in the nucleus accumbens is required for the D-amphetamine-induced release of functional dopamine.

We have previously shown that a large part of the D-amphetamine-induced release of dopamine in the nucleus accumbens is not associated with an increase in locomotor activity, and that "functional" dopamine release (i.e. release of dopamine associated with locomotor activity) requires the distal facilitation of noradrenergic transmission through alpha1-adrenergic receptors in the prefrontal cortex. To determine the role of monosynaptic or polysynaptic projections from the prefrontal cortex to the nucleus accumbens in these amphetamine responses, either AMPA/kainate (6-cyano-7-nitroquinoxaline-2,3-dione, CNQX, 300microM), N-methyl-D-aspartate (D(-)-2-amino-5-phosphono-pentanoic acid, APV, 500microM) or metabotropic [(+)-alpha-methyl-4-carboxy-phenylglycine, MCPG, 10mM] glutamate receptor antagonists were infused through a dialysis probe in the rat nucleus accumbens. CNQX and MCPG but not APV reduced the "non-functional" release of dopamine evoked by local (3microM) and systemic D-amphetamine (2mg/kg i.p.) treatments. However, the locomotor hyperactivity and functional dopamine release induced by systemic D-amphetamine were abolished by MCPG, but neither by CNQX nor by APV. MCPG treatment also abolished the hyperlocomotor activity and functional dopamine release evoked by bilateral morphine injection into the ventral tegmental area. The dopamine release evoked by this morphine treatment was 16-fold lower than that induced by the systemic D-amphetamine injection, although similar behavioral activations were observed. Altogether, our results further aid the discrimination of functional and non-functional release of dopamine. We suggest that the activation of metabotropic glutamate receptors in the nucleus accumbens is required for functional dopamine release following systemic D-amphetamine injection.

Electrophysiological evidence that noradrenergic neurons of the rat locus coeruleus are tonically inhibited by GABA during sleep.

It is well known that noradrenergic locus coeruleus (LC) neurons decrease their activity during slow wave sleep (SWS) and are virtually quiescent during paradoxical sleep (PS). It has been proposed that a GABAergic input could be directly responsible for this sleep-dependent neuronal inactivation. To test this hypothesis, we used a new method combining polygraphic recordings, microiontophoresis and single-unit extracellular recordings in unanaesthetized head-restrained rats. We found that iontophoretic application of bicuculline, a specific GABA(A)-receptor antagonist, during PS and SWS restore a tonic firing in the LC noradrenergic neurons. We further observed that the application of bicuculline during wakefulness (W) induced an increase of the discharge rate. Of particular importance for the interpretation of these results, using the microdialysis technique, Nitz and Siegel (Neuroscience, 1997; 78: 795) recently found an increase of the GABA release in the cat LC during SWS and PS as compared with waking values. Based on these and our results, we therefore propose that during W, the LC cells are under a GABAergic inhibitory tone which progressively increases at the entrance and during SWS and PS and is responsible for the inactivation of these neurons during these states.

Importance of the noradrenaline-dopamine coupling in the locomotor activating effects of D-amphetamine.

The locomotor hyperactivity induced by systemic or local (nucleus accumbens) D-amphetamine injections can be blocked by systemic or local (prefrontal cortex) injections of prazosin, an alpha1-adrenergic antagonist (Blance et al., 1994). Microdialysis studies performed on freely moving animals indicated that prazosin (0.5 mg/kg, i.p.) does not modify the increase in the extracellular dopamine (DA) levels in the nucleus accumbens that are induced by D-amphetamine (2.0 mg/kg, i.p.), but it inhibits the D-amphetamine-induced locomotor hyperactivity (-63%, p < 0.0001). No behavioral activation occurred after the bilateral local perfusion of 3 microM D-amphetamine in the nucleus accumbens, although it led to a fivefold increase in extracellular DA levels. This increase in extracellular DA levels was not affected by prazosin (0.5 mg/kg, i.p.). When an intraperitoneal injection of D-amphetamine (0.5 mg/kg) was superimposed to the continuous local perfusion of 3 microM D-amphetamine, it induced a 64% increase in the extracellular DA levels in the nucleus accumbens, and this response was associated with simultaneous behavioral activation. Both the increases in extracellular DA levels and in locomotor activity were completely blocked by a pretreatment with prazosin, injected either systemically (0.5 mg/kg, i.p.) or locally and bilaterally into the prefrontal cortex (500 pmol/side). Complementary experiments indicated that the focal application of D-amphetamine requires at least a 4.8-fold higher increase in DA output compared with systemic D-amphetamine for the behavioral effects to be elicited. Altogether, these results suggest that locomotor activating effects of D-amphetamine are caused by the stimulation of cortical alpha1-adrenergic receptors by noradrenaline, which increases the release of a functional part of subcortical DA.

Effect of strychnine on rat locus coeruleus neurones during sleep and wakefulness.

The noradrenergic neurones of the locus coeruleus (LC) discharge tonically during wakefulness, decrease their activity during slow wave sleep and are virtually quiescent during paradoxical sleep. We recently demonstrated an inhibitory glycinergic input to the locus coeruleus and proposed that this could be responsible for inhibition of the LC during paradoxical sleep. To test this proposal, we developed a method combining polygraphic recordings, iontophoresis and single-unit extracellular recordings in the unanaesthetized head-restrained rat. Iontophoretically applied strychnine, a specific glycine antagonist, induced strong excitation of LC neurones during paradoxical sleep, but also during slow wave sleep and wakefulness. These results suggest that glycine tonically inhibits noradrenergic LC neurones throughout the entire sleep-waking cycle and not only during paradoxical sleep.