脑内轴突铁转运调节焦虑相关行为。

Axonal iron transport in the brain modulates anxiety-related behaviors.

机构信息

Institute of Mental Health, Southern Medical University, Guangzhou, China.

Key Laboratory of Mental Health of the Ministry of Education and Guangdong Province Key Laboratory of Psychiatric Disorders, Guangzhou, China.

出版信息

Nat Chem Biol. 2019 Dec;15(12):1214-1222. doi: 10.1038/s41589-019-0371-x. Epub 2019 Oct 7.

DOI:10.1038/s41589-019-0371-x

PMID:31591566

Abstract

Iron is essential for a broad range of biochemical processes in the brain, but the mechanisms of iron metabolism in the brain remain elusive. Here we show that iron functionally translocates among brain regions along specific axonal projections. We identified two pathways for iron transport in the brain: a pathway from ventral hippocampus (vHip) to medial prefrontal cortex (mPFC) to substantia nigra; and a pathway from thalamus (Tha) to amygdala (AMG) to mPFC. While vHip-mPFC transport modulates anxiety-related behaviors, impairment of Tha-AMG-mPFC transport did not. Moreover, vHip-mPFC iron transport is necessary for the behavioral effects of diazepam, a well-known anxiolytic drug. By contrast, genetic or pharmacological promotion of vHip-mPFC transport produced anxiolytic-like effects and restored anxiety-like behaviors induced by repeated restraint stress. Taken together, these findings provide key insights into iron metabolism in the brain and identify the mechanisms underlying iron transport in the brain as a potential target for development of novel anxiety treatments.

摘要

铁是大脑中广泛的生化过程所必需的，但大脑中铁代谢的机制仍难以捉摸。在这里，我们表明铁可以沿着特定的轴突投射在脑区之间进行功能转移。我们在大脑中确定了两种铁运输途径：一种是从腹侧海马体（vHip）到前额叶皮层（mPFC）到黑质的途径；另一种是从丘脑（Tha）到杏仁核（AMG）到 mPFC 的途径。虽然 vHip-mPFC 运输调节与焦虑相关的行为，但 Tha-AMG-mPFC 运输的损伤不会。此外，vHip-mPFC 铁运输对于苯并二氮䓬类药物（一种众所周知的抗焦虑药物）的行为效应是必要的。相比之下，vHip-mPFC 运输的遗传或药物促进作用产生了抗焦虑样作用，并恢复了由重复束缚应激引起的焦虑样行为。总之，这些发现为大脑中铁代谢提供了关键的见解，并确定了大脑中铁运输的机制作为开发新型焦虑治疗方法的潜在目标。

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脑内轴突铁转运调节焦虑相关行为。

Axonal iron transport in the brain modulates anxiety-related behaviors.

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