Alterations in noradrenergic neurotransmission are important in the mechanism of action of many antidepressant drugs, including selective norepinephrine (NA) reuptake inhibitors such as desipramine (DMI). It has been suggested that chronic NA reuptake blockade induces a desensitization of inhibitory a 2 -adrenergic autoreceptors. This hypothesis was tested in experiment 1 using in vivo microdialysis to examine the degree of a 2 -autoreceptor-mediated inhibition of NA release in rat medial prefrontal cortex exerted by endogenous NA following chronic treatment with vehicle or DMI. This was accomplished by measuring the elevation of extracellular NA levels induced by acute administration of the a 2 -receptor antagonist yohimbine. An 8-fold increase in basal NA levels was observed after 21 days of DMI treatment. Further, acute yohimbine administration induced a robust elevation in NA levels which was not attenuated, and in fact at lower doses was greater in DMI-treated rats compared with vehicle-treated controls. In experiment 2, we addressed directly the functional status of terminal a 2 -autoreceptors in frontal cortex in vitro, in the absence of potentially confounding competition from elevated levels of endogenous NA, after chronic reuptake blockade. We observed no difference in the degree to which the a 2 -receptor agonist clonidine inhibited potassium-evoked [ 3 H]-NA release from cortical slices taken from DMI-or vehicle-treated rats. Together, these data suggest that endogenous activation of a 2 -autoreceptors persists in restraining NA neurotransmission in the face of tonically elevated basal NA levels following chronic reuptake blockade.
Galanin is colocalized extensively with norepinephrine in brain. Although this suggests possible activity-dependent neurotransmitter interactions, the functional significance of such colocalization remains elusive. Previously, we showed that enhancing stress-activation of the noradrenergic system by yohimbine pretreatment released galanin in central amygdala, attenuating the anxiety-like behavioral response to stress on the elevated plus-maze. The present study was conducted to determine, in this context, whether galanin was indeed coreleased from noradrenergic terminals, or instead from another galanin afferent or local stress-responsive galanin neurons in the amygdala. In experiment 1, galanin-mediated anxiolytic effects on the plus-maze following yohimbine + stress were unaltered by lesioning the noradrenergic innervation of central amygdala. In experiment 2, combining immunohistochemistry and in situ hybridization, galanin neurons specifically activated by yohimbine + stress treatment were found only in the locus coeruleus and intraamygdalar bed nucleus of the stria terminalis, adjacent to central amygdala. In experiment 3, retrograde tracing combined with in situ hybridization revealed few if any galanin cells projecting to central amygdala in locus coeruleus or nucleus tractus solitarius, sources of noradrenergic innervation. Indeed, few retrogradely-labeled galanin neurons were observed anywhere in the brain, including a small number in the intraamygdalar bed nucleus. Together, these results suggest that stress following yohimbine may have induced galanin release from an afferent to central amygdala originating in the bed nucleus, or from local neurons in the intraamygdalar bed nucleus, but that anxiolytic effects exerted by galanin in this context of elevated noradrenergic activity were not the result of corelease from noradrenergic terminals innervating central amygdala.
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