Benzodiazepine binding sites in the cingulate cortex after lesion of the noradrenaline and dopamine containing afferents

The autoradiographic perspective of central benzodiazepine receptors; a short review

1. We reviewed studies performed to characterize central benzodiazepine binding sites. 2. An overview of the different radioligands used to characterize BZ1 and BZ2 binding sites and a mapping of these central benzodiazepine sites are described. 3. Saturation studies carried out by autoradiogram quantification also are reviewed. 4. The specific use of the autoradiographic technique to carry out studies on ontogeny, development, and phylogeny is discussed, as well as studies performed using this technique on some diseases and experimental conditions, such as drug treatments or chemical and mechanical lesions.

Autoradiographic study on [3H]flunitrazepam binding in rat cortex and hippocampus after chronic ethanol treatment

Ethanol alters almost all membrane functions, but it behaves essentially like a benzodiazepine-type GABAergic agonist. The mechanism by which ethanol affects the GABA/benzodiazepine complex is not clear. We studied the possible changes in [3H]flunitrazepam binding induced by chronic ethanol treatment, using light microscopic autoradiography, to try to elucidate the controversy underlying this topic. This technique allows us to measure densities of benzodiazepine receptors in different anatomical brain areas--visual cortex and hippocampus--which seem to constitute the anatomical support for the behavioral and physiological responses affected by ethanol. Autoradiographic studies on the visual cortex and hippocampus from rats chronically treated with ethanol do not show statistically significant differences in the binding of [3H]flunitrazepam with respect to control animals. Furthermore, we did not find either rostro-caudal or medio-lateral differences in benzodiazepine receptor densities in each layer of the visual cortex.

The anxiogenic beta-carboline FG-7142 increases in vivo and in vitro tyrosine hydroxylation in the prefrontal cortex

Systemic administration of the anxiogenic beta-carboline FG-7142, a benzodiazepine inverse agonist, results in a regionally selective increase in dopamine (DA) utilization in the anteromedial prefrontal cortex (PFC). We have examined both in vivo and in vitro tyrosine hydroxylation in the PFC and other mesotelencephalic DA system terminal fields in order to determine if FG-7142 effects changes in DA synthesis, and to determine if the beta-carboline biochemically activates certain DA neurons through an action occurring at the cell body level (impulse-dependent regulation) or at the terminal field level (presynaptic regulation). FG-7142 increased in vivo tyrosine hydroxylation in the PFC and in the ventral tegmental area, midbrain source of the DA innervation of the PFC; no changes were observed in mesolimbic or nigrostriatal regions. The beta-carboline also increased in vitro tyrosine hydroxylation in the PFC, but decreased tyrosine hydroxylation in striatal slices. The effects of FG-7142 were blocked by the benzodiazepine antagonist RO 15-1788. Another beta-carboline inverse agonist, methyl-beta-carboline-3-carboline-3-carboxylate, also increased in vitro tyrosine hydroxylation in the PFC. GABA exerted opposite effects to those of the beta-carbolines, decreasing in vitro tyrosine hydroxylation in the PFC and increasing DA synthesis in the CP. These data indicate that the benzodiazepine inverse agonists increase both in vivo and in vitro tyrosine hydroxylation in the PFC, and that the beta-carboline may act to increase DA synthesis at both the terminal field and the cell body level.