Clark Lyles R, Yun Sanghee, Acquah Nana K, Kumar Priya L, Metheny Hannah E, Paixao Rikley C C, Cohen Akivas S, Eisch Amelia J
Department of Anesthesiology and Critical Care Medicine, The Children's Hospital of Philadelphia (CHOP) Research Institute, Philadelphia, PA, United States.
Mahoney Institute for Neurosciences, Perelman School of Medicine, Philadelphia, PA, United States.
Front Neurosci. 2021 Jan 7;14:612749. doi: 10.3389/fnins.2020.612749. eCollection 2020.
Mild traumatic brain injuries (mTBIs) are prevalent worldwide. mTBIs can impair hippocampal-based functions such as memory and cause network hyperexcitability of the dentate gyrus (DG), a key entry point to hippocampal circuitry. One candidate for mediating mTBI-induced hippocampal cognitive and physiological dysfunction is injury-induced changes in the process of DG neurogenesis. There are conflicting results on how TBI impacts the process of DG neurogenesis; this is not surprising given that both the neurogenesis process and the post-injury period are dynamic, and that the quantification of neurogenesis varies widely in the literature. Even within the minority of TBI studies focusing specifically on mild injuries, there is disagreement about if and how mTBI changes the process of DG neurogenesis. Here we utilized a clinically relevant rodent model of mTBI (lateral fluid percussion injury, LFPI), gold-standard markers and quantification of the neurogenesis process, and three time points post-injury to generate a comprehensive picture of how mTBI affects adult hippocampal DG neurogenesis. Male C57BL/6J mice (6-8 weeks old) received either sham surgery or mTBI via LFPI. Proliferating cells, neuroblasts/immature neurons, and surviving cells were quantified via stereology in DG subregions (subgranular zone [SGZ], outer granule cell layer [oGCL], molecular layer, and hilus) at short-term (3 days post-injury, dpi), intermediate (7 dpi), and long-term (31 dpi) time points. The data show this model of mTBI induces transient, sequential increases in ipsilateral SGZ/GCL proliferating cells, neuroblasts/immature neurons, and surviving cells which is suggestive of mTBI-induced neurogenesis. In contrast to these ipsilateral hemisphere findings, measures in the contralateral hemisphere were not increased in key neurogenic DG subregions after LFPI. Our work in this mTBI model is in line with most literature on other and more severe models of TBI in showing TBI stimulates the process of DG neurogenesis. However, as our DG data in mTBI provide temporal, subregional, and neurogenesis-stage resolution, these data are important to consider in regard to the functional importance of TBI-induction of the neurogenesis process and future work assessing the potential of replacing and/or repairing DG neurons in the brain after TBI.
轻度创伤性脑损伤(mTBI)在全球范围内普遍存在。mTBI会损害基于海马体的功能,如记忆,并导致齿状回(DG)的网络兴奋性过高,而齿状回是海马体回路的关键入口点。介导mTBI诱导的海马体认知和生理功能障碍的一个候选因素是损伤诱导的DG神经发生过程的变化。关于创伤性脑损伤如何影响DG神经发生过程,存在相互矛盾的结果;考虑到神经发生过程和损伤后时期都是动态的,而且文献中神经发生的量化差异很大,这并不奇怪。即使在少数专门关注轻度损伤的创伤性脑损伤研究中,对于mTBI是否以及如何改变DG神经发生过程也存在分歧。在这里,我们利用了一种临床相关的mTBI啮齿动物模型(侧方流体冲击伤,LFPI)、神经发生过程的金标准标记物和量化方法,以及损伤后的三个时间点,以全面了解mTBI如何影响成年海马体DG神经发生。雄性C57BL/6J小鼠(6-8周龄)接受假手术或通过LFPI进行mTBI。在短期(损伤后3天,dpi)、中期(7 dpi)和长期(31 dpi)时间点,通过体视学对DG亚区域(颗粒下区[SGZ]、外颗粒细胞层[oGCL]、分子层和齿状回)中的增殖细胞、神经母细胞/未成熟神经元和存活细胞进行量化。数据显示,这种mTBI模型诱导同侧SGZ/GCL增殖细胞、神经母细胞/未成熟神经元和存活细胞出现短暂的、相继的增加,这提示了mTBI诱导的神经发生。与这些同侧半球的发现相反,LFPI后对侧半球关键神经源性DG亚区域的测量值没有增加。我们在这个mTBI模型中的工作与大多数关于其他更严重创伤性脑损伤模型的文献一致,表明创伤性脑损伤会刺激DG神经发生过程。然而,由于我们在mTBI中的DG数据提供了时间、亚区域和神经发生阶段的分辨率,这些数据对于考虑创伤性脑损伤诱导神经发生过程的功能重要性以及未来评估创伤性脑损伤后替换和/或修复大脑中DG神经元潜力的工作具有重要意义。
