Orexin/Hypocretin and Organizing Principles for a Diversity of Wake-Promoting Neurons in the Brain.

IF 0.9 4区 环境科学与生态学 Q2 Agricultural and Biological Sciences
Cornelia Schöne, Denis Burdakov
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引用次数: 32

Abstract

An enigmatic feature of behavioural state control is the rich diversity of wake-promoting neural systems. This diversity has been rationalized as 'robustness via redundancy', wherein wakefulness control is not critically dependent on one type of neuron or molecule. Studies of the brain orexin/hypocretin system challenge this view by demonstrating that wakefulness control fails upon loss of this neurotransmitter system. Since orexin neurons signal arousal need, and excite other wake-promoting neurons, their actions illuminate nonredundant principles of arousal control. Here, we suggest such principles by reviewing the orexin system from a collective viewpoint of biology, physics and engineering. Orexin peptides excite other arousal-promoting neurons (noradrenaline, histamine, serotonin, acetylcholine neurons), either by activating mixed-cation conductances or by inhibiting potassium conductances. Ohm's law predicts that these opposite conductance changes will produce opposite effects on sensitivity of neuronal excitability to current inputs, thus enabling orexin to differentially control input-output gain of its target networks. Orexin neurons also produce other transmitters, including glutamate. When orexin cells fire, glutamate-mediated downstream excitation displays temporal decay, but orexin-mediated excitation escalates, as if orexin transmission enabled arousal controllers to compute a time integral of arousal need. Since the anatomical and functional architecture of the orexin system contains negative feedback loops (e.g. orexin ➔ histamine ➔ noradrenaline/serotonin-orexin), such computations may stabilize wakefulness via integral feedback, a basic engineering strategy for set point control in uncertain environments. Such dynamic behavioural control requires several distinct wake-promoting modules, which perform nonredundant transformations of arousal signals and are connected in feedback loops.

Orexin/Hypocytin和大脑中唤醒促进神经元多样性的组织原理。
行为状态控制的一个神秘特征是唤醒促进神经系统的丰富多样性。这种多样性被合理化为“通过冗余的鲁棒性”,其中清醒控制并不严重依赖于一种类型的神经元或分子。对大脑食欲素/下丘脑视网膜系统的研究对这一观点提出了质疑,因为研究表明,一旦失去这种神经递质系统,清醒控制就会失效。由于食欲素神经元发出唤醒需求的信号,并刺激其他促醒神经元,它们的行为阐明了唤醒控制的非冗余原则。在这里,我们从生物学、物理学和工程学的共同角度回顾食欲素系统,提出了这些原则。Orexin肽通过激活混合阳离子电导或抑制钾电导来刺激其他促觉醒神经元(去甲肾上腺素、组胺、血清素、乙酰胆碱神经元)。欧姆定律预测,这些相反的电导变化将对神经元兴奋性对电流输入的敏感性产生相反的影响,从而使食欲素能够差分地控制其目标网络的输入输出增益。Orexin神经元还产生其他递质,包括谷氨酸。当食欲素细胞激发时,谷氨酸介导的下游兴奋表现出时间衰减,但食欲素介导的兴奋升级,就好像食欲素的传递使唤醒控制器能够计算唤醒需求的时间积分一样。由于食欲素系统的解剖和功能结构包含负反馈回路(例如食欲素➔ 组胺➔ 去甲肾上腺素/血清素食欲素),这样的计算可以通过积分反馈来稳定清醒,积分反馈是不确定环境中设定点控制的基本工程策略。这种动态行为控制需要几个不同的促醒模块,这些模块对唤醒信号进行非冗余转换,并在反馈回路中连接。
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来源期刊
自引率
0.00%
发文量
14
期刊介绍: The African Journal of Wildlife Research is an ISI ranked, leading peer reviewed scientific publication in wildlife research in Africa, Arabia and Madagascar, with a broad base covering scientific, applied, managerial, methodological and sociological issues related to wildlife research. The journal publishes original full-length scientific papers, short communications, book reviews as well as reviews on science-based research invited by the editor-in-chief. This research journal and has been published annually since 1971. Until 2014 (Volume 44) the journal was known as the South African Journal of Wildlife Research and from 2015 (volume 45) the name changed to African Journal of Wildlife Research. The journal reaches a wide readership, including both local and foreign wildlife managers, academics and wildlife owners, and libraries local and abroad. It is an important reference for anyone interested in the management and sustainable utilisation of natural resources.
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