The authors used an intersectional genetic strategy to comprehensively target axo-axonic interneurons (AACs) across the mouse brain. They discovered that AACs are present in essentially all pallium-derived brain structures, including the neocortex, hippocampus, claustrum-insular complex, extended amygdala, and olfactory centers.
In the neocortex, the authors quantified the areal, laminar, and morphological diversity of AACs. They found that AACs exhibit characteristic laminar distribution patterns, with the majority occupying a narrow band just below the layer 1/2 border, and a smaller proportion forming a second band above the white matter. Sparse labeling revealed multiple AAC subtypes, including supragranular, infragranular, and translaminar types.
In the hippocampus, AACs were most abundant in CA2, with sparser populations in CA1, CA3, and dentate gyrus. In the amygdala and olfactory centers, AACs exhibited more multipolar morphologies compared to the laminar patterns observed in the cortex and hippocampus.
The authors further used an intersectional viral tracing approach to map the long-range synaptic inputs to AACs in sensorimotor cortical areas and the CA1 region of the hippocampus. AACs received inputs from diverse sources, including motor, sensory, and other cortical areas, as well as thalamic and subcortical regions. The input patterns differed between AACs and parvalbumin-expressing interneurons, suggesting distinct functional roles.
Overall, this study provides a comprehensive mapping of AACs across the mouse brain and reveals their diverse distribution, morphological subtypes, and synaptic connectivity, setting the stage for understanding their role in circuit development and function.
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by Raudales,R.,... 場所 www.biorxiv.org 11-08-2023
https://www.biorxiv.org/content/10.1101/2023.11.07.566059v2深掘り質問