Hypothalamic Orexinergic Neurons Projecting to the Mesencephalic Locomotor Region Are Activated by Voluntary Wheel Running Exercise in Rats.

IF 0.9 4区医学 Q4 MEDICINE, RESEARCH & EXPERIMENTAL Yonago acta medica Pub Date : 2024-01-12 eCollection Date: 2024-02-01 DOI:10.33160/yam.2024.02.006

Emi Narai, Tatsuo Watanabe, Satoshi Koba

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Abstract

Background: Cardiovascular changes during exercise are regulated by a motor volitional signal, called central command, which originates in the rostral portions of the brain and simultaneously regulates somatomotor and autonomic nervous systems. Whereas we recently elucidated mesencephalic locomotor region (MLR) neurons projecting to the rostral ventrolateral medulla as a crucial component of the central circuit responsible for transmitting central command signals, upstream circuits that regulate the MLR neurons remain unknown. Orexinergic neurons, which primarily originate from the perifornical area (PeFA) of the hypothalamus and reportedly play roles in eliciting locomotion and elevating sympathetic activity, send axonal projection to the MLR. The knowledge led us to investigate whether central command signals are relayed through orexinergic neurons projecting to the MLR.

Methods: We performed anterograde transsynaptic tagging with AAV1 encoding Cre to confirm the presence of MLR neurons postsynaptic to the PeFA in rats. We also conducted retrograde neural tracing with retrograde AAV, combined with immunohistochemical staining, to examine the excitability of MLR-projecting orexinergic neurons in rats that were allowed to freely run on the wheel for 90 min.

Results: A significant number of MLR neurons were labeled with Cre, indicating that PeFA neurons make synaptic contacts with MLR neurons. Moreover, immunoreactivities of Fos, a marker of neuronal excitation, were found in many MLR-projecting orexinergic neurons by voluntary wheel running exercise, compared to non-exercising control rats, especially in the intermediate-posterior, rather than anterior, and medial, rather than lateral, portions within the orexinergic neuron-distributing domain.

Conclusion: The findings suggest that specifically located orexinergic neurons transmit central command signals onto the MLR for running exercise. Elucidating the role of these MLR-projecting orexinergic neurons in somatomotor control and autonomic cardiovascular control deserves further study to unveil central circuit mechanisms responsible for central command function.

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大鼠自主轮跑运动激活了投射到间脑运动区的下丘脑肾上腺素能神经元

背景：运动时的心血管变化受运动意志信号的调节，这种信号被称为中枢指令，它起源于大脑的喙突部分，同时调节躯体运动和自主神经系统。虽然我们最近阐明了投射到喙腹外侧延髓的间脑运动区（MLR）神经元是负责传递中枢指令信号的中枢回路的重要组成部分，但调节间脑运动区神经元的上游回路仍然未知。据报道，肾上腺素能神经元主要起源于下丘脑的腓周区（PeFA），在诱发运动和提高交感神经活动方面发挥作用，并向MLR发出轴突投射。这些知识促使我们研究中枢指令信号是否通过投射到MLR的奥曲肽能神经元传递：方法：我们用编码 Cre 的 AAV1 进行了前向突触标记，以证实大鼠存在突触后投射到 PeFA 的 MLR 神经元。我们还用逆行 AAV 进行了逆行神经追踪，并结合免疫组化染色，以检查让大鼠在车轮上自由奔跑 90 分钟后，MLR 投射的奥曲肽能神经元的兴奋性：结果：大量MLR神经元被Cre标记，表明PeFA神经元与MLR神经元有突触接触。此外，与不运动的对照组大鼠相比，通过自愿车轮跑步运动，在许多投射于 MLR 的奥曲肽能神经元中发现了神经元兴奋标记物 Fos 的免疫反应活性，尤其是在奥曲肽能神经元分布区的中后部而不是前部，以及内侧而不是外侧：结论：研究结果表明，位于特定位置的奥曲肽能神经元将中枢指令信号传送到MLR，以促进跑步运动。阐明这些投射到 MLR 的奥曲肽能神经元在躯体运动控制和自主心血管控制中的作用值得进一步研究，以揭示负责中枢指挥功能的中枢回路机制。

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来源期刊

Yonago acta medica MEDICINE, RESEARCH & EXPERIMENTAL-

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Yonago Acta Medica (YAM) is an electronic journal specializing in medical sciences, published by Tottori University Medical Press, 86 Nishi-cho, Yonago 683-8503, Japan. The subject areas cover the following: molecular/cell biology; biochemistry; basic medicine; clinical medicine; veterinary medicine; clinical nutrition and food sciences; medical engineering; nursing sciences; laboratory medicine; clinical psychology; medical education. Basically, contributors are limited to members of Tottori University and Tottori University Hospital. Researchers outside the above-mentioned university community may also submit papers on the recommendation of a professor, an associate professor, or a junior associate professor at this university community. Articles are classified into four categories: review articles, original articles, patient reports, and short communications.