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Whole-brain spatial organization of hippocampal single-neuron projectomes.

Shou QiuYachuang HuYiming HuangTaosha GaoXiaofei WangDanying WangBiyu RenXiaoxue ShiYu ChenXinran WangDan WangLuyao HanYikai LiangDechen LiuQingxu LiuLi DengZhaoqin ChenLijie ZhanTianzhi ChenYuzhe HuangQingge WuTaorong XieLiuqin QianChenxi JinJiawen HuangWei DengTao JiangXiangning LiXueyan JiaJing YuanAnan LiJun YanNing-Long XuFu-Qiang XuQingming LuoMu-Ming PooYi-Di SunChengyu T LiHaishan YaoHui GongYan-Gang SunChun Xu
Published in: Science (New York, N.Y.) (2024)
Mapping single-neuron projections is essential for understanding brain-wide connectivity and diverse functions of the hippocampus (HIP). Here, we reconstructed 10,100 single-neuron projectomes of mouse HIP and classified 43 projectome subtypes with distinct projection patterns. The number of projection targets and axon-tip distribution depended on the soma location along HIP longitudinal and transverse axes. Many projectome subtypes were enriched in specific HIP subdomains defined by spatial transcriptomic profiles. Furthermore, we delineated comprehensive wiring diagrams for HIP neurons projecting exclusively within the HIP formation (HPF) and for those projecting to both intra- and extra-HPF targets. Bihemispheric projecting neurons generally projected to one pair of homologous targets with ipsilateral preference. These organization principles of single-neuron projectomes provide a structural basis for understanding the function of HIP neurons.
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