Spontaneously regenerative corticospinal neurons in mice

Benjamin W Fait, Bianca Cotto, Tatsuya C Murakami, Michael Hagemann-Jensen, Huiqing Zhan, Corinne Freivald, Isadora Turbek, Yuan Gao, Zizhen Yao, Sharon W Way, Hongkui Zeng, Bosiljka Tasic, Oswald Steward, Nathaniel Heintz, Eric F Schmidt
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Abstract

The spinal cord receives inputs from the cortex via corticospinal neurons (CSNs). While predominantly a contralateral projection, a less-investigated minority of its axons terminate in the ipsilateral spinal cord. We analyzed the spatial and molecular properties of these ipsilateral axons and their post-synaptic targets in mice and found they project primarily to the ventral horn, including directly to motor neurons. Barcode-based reconstruction of the ipsilateral axons revealed a class of primarily bilaterally-projecting CSNs with a distinct cortical distribution. The molecular properties of these ipsilaterally-projecting CSNs (IP-CSNs) are strikingly similar to the previously described molecular signature of embryonic-like regenerating CSNs. Finally, we show that IP-CSNs are spontaneously regenerative after spinal cord injury. The discovery of a class of spontaneously regenerative CSNs may prove valuable to the study of spinal cord injury. Additionally, this work suggests that the retention of juvenile-like characteristics may be a widespread phenomenon in adult nervous systems.
小鼠自发性再生皮质脊髓神经元
脊髓通过皮质脊髓神经元(CSN)接收来自大脑皮层的输入。虽然主要是对侧投射,但其少数轴突终止于同侧脊髓,这一点较少被研究。我们分析了小鼠同侧轴突及其突触后靶点的空间和分子特性,发现它们主要投射到腹角,包括直接投射到运动神经元。基于条形码的同侧轴突重建揭示了一类主要向双侧投射的 CSN,它们在皮层的分布十分明显。这些同侧投射的 CSNs(IP-CSNs)的分子特性与之前描述的胚胎样再生 CSNs 分子特征惊人地相似。最后,我们证明 IP-CSNs 在脊髓损伤后可自发再生。一类自发再生 CSNs 的发现可能对脊髓损伤的研究很有价值。此外,这项工作还表明,保留类似幼年期的特征可能是成人神经系统中的一种普遍现象。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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