{"title":"Hibernation reduces GABA signaling in the brainstem to enhance motor activity of breathing at cool temperatures.","authors":"Sandy E Saunders, Joseph M Santin","doi":"10.1101/2023.10.09.561534","DOIUrl":null,"url":null,"abstract":"<p><strong>Background: </strong>Neural circuits produce reliable activity patterns despite disturbances in the environment. For this to occur, neurons elicit synaptic plasticity during perturbations. However, recent work suggests that plasticity not only regulates circuit activity during disturbances, but these modifications may also linger to stabilize circuits during future perturbations. The implementation of such a regulation scheme for real-life environmental challenges of animals remains unclear. Amphibians provide insight into this problem in a rather extreme way, as circuits that generate breathing are inactive for several months during underwater hibernation and use compensatory plasticity to promote ventilation upon emergence.</p><p><strong>Results: </strong>Using <i>ex vivo</i> brainstem preparations and electrophysiology, we find that hibernation in American bullfrogs reduces GABA<sub>A</sub> receptor (GABA<sub>A</sub>R) inhibition in respiratory rhythm generating circuits and motor neurons, consistent with a compensatory response to chronic inactivity. Although GABA<sub>A</sub>Rs are normally critical for breathing, baseline network output at warm temperatures was not affected. However, when assessed across a range of temperatures, hibernators with reduced GABA<sub>A</sub>R signaling had greater activity at cooler temperatures, enhancing respiratory motor output under conditions that otherwise strongly depress breathing.</p><p><strong>Conclusions: </strong>Hibernation reduces GABA<sub>A</sub>R signaling to promote robust respiratory output only at cooler temperatures. Although animals do not ventilate lungs during hibernation, we suggest this would be beneficial for stabilizing breathing when the animal passes through a large temperature range during emergence in the spring. More broadly, these results demonstrate that compensatory synaptic plasticity can increase the operating range of circuits in harsh environments, thereby promoting adaptive behavior in conditions that suppress activity.</p>","PeriodicalId":72407,"journal":{"name":"bioRxiv : the preprint server for biology","volume":" ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-10-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10592683/pdf/nihpp-2023.10.09.561534v1.pdf","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"bioRxiv : the preprint server for biology","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1101/2023.10.09.561534","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Background: Neural circuits produce reliable activity patterns despite disturbances in the environment. For this to occur, neurons elicit synaptic plasticity during perturbations. However, recent work suggests that plasticity not only regulates circuit activity during disturbances, but these modifications may also linger to stabilize circuits during future perturbations. The implementation of such a regulation scheme for real-life environmental challenges of animals remains unclear. Amphibians provide insight into this problem in a rather extreme way, as circuits that generate breathing are inactive for several months during underwater hibernation and use compensatory plasticity to promote ventilation upon emergence.
Results: Using ex vivo brainstem preparations and electrophysiology, we find that hibernation in American bullfrogs reduces GABAA receptor (GABAAR) inhibition in respiratory rhythm generating circuits and motor neurons, consistent with a compensatory response to chronic inactivity. Although GABAARs are normally critical for breathing, baseline network output at warm temperatures was not affected. However, when assessed across a range of temperatures, hibernators with reduced GABAAR signaling had greater activity at cooler temperatures, enhancing respiratory motor output under conditions that otherwise strongly depress breathing.
Conclusions: Hibernation reduces GABAAR signaling to promote robust respiratory output only at cooler temperatures. Although animals do not ventilate lungs during hibernation, we suggest this would be beneficial for stabilizing breathing when the animal passes through a large temperature range during emergence in the spring. More broadly, these results demonstrate that compensatory synaptic plasticity can increase the operating range of circuits in harsh environments, thereby promoting adaptive behavior in conditions that suppress activity.
呼吸网络必须在动物的一生中产生一致的输出。尽管呼吸运动的可塑性得到了很好的理解,但在干扰呼吸的扰动之后,可塑性机制是如何组织起来以产生鲁棒性的还不太清楚。在水下冬眠期间,牛蛙的呼吸神经元在数月内保持不活动状态,这提供了一种必须克服的巨大干扰才能重新开始呼吸。因此,运动神经元上调兴奋性突触,以促进呼吸的动力。抑制作用的减少通常与兴奋作用的增加同时发生,但抑制作用的丧失会使呼吸运动输出不稳定。因此,我们假设GABA能抑制在冬眠后会减少,但这种减少在整个网络中会有不同的表达。我们证实呼吸频率受GABA A A R信号的控制,但在冬眠后,它对抑制的依赖性降低了。抑制作用的丧失仅限于呼吸节律产生中心:对照组和冬眠者的GABA A受体阻断同样会引发非呼吸运动活动和大发作样发作。支持突触前GABA释放减少,呼吸运动神经元的放电速率受到时相GABA a a R音调的限制,但在冬眠后,尽管与对照组具有相同的突触后受体强度,但这种音调还是降低了。因此,选择性地减少呼吸前运动网络中的抑制可以促进呼吸的稳定性,而GABA A A Rs的大量缺失会导致整个脑干的非特异性超兴奋性。这些结果表明,呼吸网络的不同部分选择了不同的策略,包括兴奋(运动神经元)或抑制(节律发生器),以在参与保护呼吸动力的可塑性时最大限度地减少病理网络状态。
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