GABAA receptor subunits in the human amygdala and hippocampus: Immunohistochemical distribution of 7 subunits.

GABAergic neurotransmission in the amygdala contributes to the regulation of emotional processes in anxiety, stress, reward, mnestic functions, addiction, and epilepsy. Species-specific differences in the distribution and composition of GABAA receptors may account for distinct effects and side-effects of GABAergic agents. However, data on the distribution and composition of GABAA receptors in the human amygdala are lacking. Here, the expression of GABAA receptor subunits α1, α2, α3, α5, ß2, ß2/3, and γ2 was studied in the human amygdala using immunohistochemistry. Hippocampi were evaluated as a reference structure. Neuronal counts and field fraction analyses were performed, and subcellular expression of GABAA receptor subunits was analyzed semiquantitatively. In the amygdala, field fraction analyses showed the highest α1 expression in the lateral nucleus (La), whereas α3 was prominent in intercalated nuclei (IC), and α5 and γ2 in the cortical nuclei, and amygdalo-hippocampal/parahippocampal-amygdala transition areas. In the hippocampus, α1 and α3 were accentuated in the dentate gyrus, CA1 region, and subiculum, whereas α5 expression was rather uniform. In both regions, α2 was homogenously distributed, and the two ß subunits and γ2 showed faint immunostaining. The intensity of subunit expression also varied in the neuropil, neuronal somata, and/or cellular processes in the subregions. GABAA receptors containing subunit α1, showing the strongest expression in the La, and α3, with the strongest expression in the IC and subiculum, could be targets for treating amygdala-related disorders. Differences in GABAA receptor subunit expression between the human and rodent amygdala should be taken into consideration when developing subunit-selective drugs.

A novel relay nucleus between the inferior colliculus and the optic tectum in the chicken (Gallus gallus).

Processing multimodal sensory information is vital for behaving animals in many contexts. The barn owl, an auditory specialist, is a classic model for studying multisensory integration. In the barn owl, spatial auditory information is conveyed to the optic tectum (TeO) by a direct projection from the external nucleus of the inferior colliculus (ICX). In contrast, evidence of an integration of visual and auditory information in auditory generalist avian species is completely lacking. In particular, it is not known whether in auditory generalist species the ICX projects to the TeO at all. Here we use various retrograde and anterograde tracing techniques both in vivo and in vitro, intracellular fillings of neurons in vitro, and whole-cell patch recordings to characterize the connectivity between ICX and TeO in the chicken. We found that there is a direct projection from ICX to the TeO in the chicken, although this is small and only to the deeper layers (layers 13-15) of the TeO. However, we found a relay area interposed among the IC, the TeO, and the isthmic complex that receives strong synaptic input from the ICX and projects broadly upon the intermediate and deep layers of the TeO. This area is an external portion of the formatio reticularis lateralis (FRLx). In addition to the projection to the TeO, cells in FRLx send, via collaterals, descending projections through tectopontine-tectoreticular pathways. This newly described connection from the inferior colliculus to the TeO provides a solid basis for visual-auditory integration in an auditory generalist bird. J. Comp. Neurol. 525:513-534, 2017. © 2016 Wiley Periodicals, Inc.