Department of Anesthesiology, Box 6, State University of New York Downstate Medical Center, 450 Clarkson Avenue, Brooklyn, NY 11203, USA.
J Physiol. 2012 Aug 15;590(16):4093-107. doi: 10.1113/jphysiol.2012.233965. Epub 2012 Jun 6.
Anaesthetic preconditioning occurs when a volatile anaesthetic, such as sevoflurane, is administered before a hypoxic or ischaemic insult; this has been shown to improve neuronal recovery after the insult. We found that sevoflurane-induced preconditioning in the rat hippocampal slice enhances the hypoxic hyperpolarization of CA1 pyramidal neurons, delays and attenuates their hypoxic depolarization, and increases the number of neurons that recover their resting and action potentials after hypoxia. These altered electrophysiological effects and the improved recovery corresponded with an increase in the amount of a constitutively active, atypical protein kinase C isoform found in brain, protein kinase M zeta (PKMζ). A selective inhibitor of this kinase, zeta inhibitory peptide (ZIP), blocked the increase in the total amount of PKMζ protein and the amount of the activated form of this kinase, phospho-PKMζ (p-PKMζ); it also blocked the altered electrophysiological effects and the improved recovery. We found that both cycloheximide, a general protein synthesis inhibitor, and rapamycin, a selective inhibitor of the mTOR pathway for regulating protein synthesis, blocked the increase in p-PKMζ, the electrophysiological changes, and the improved recovery due to sevoflurane-induced preconditioning. Glibenclamide, a KATP channel blocker, when present only during the hypoxia, prevented the enhanced hyperpolarization, the delayed and attenuated hypoxic depolarization, and the improved recovery following sevoflurane-induced preconditioning. To examine the function of persistent PKMζ and KATP channel activity after the preconditioning was established, we administered 4% sevoflurane for 30 min and then discontinued it for 30 min before 10 min of hypoxia. When either tolbutamide, a KATP channel blocker, or ZIP were administered at least 15 min after the washout of sevoflurane, there was little recovery compared with sevoflurane alone. Thus, continuous KATP channel and PKMζ activity are required to maintain preconditioning protection. We conclude that sevoflurane induces activation of the mTOR pathway, increasing the new protein synthesis of PKMζ, which is constitutively phosphorylated to its active form, leading to an increased KATP channel-induced hyperpolarizaton. This hyperpolarization delays and attenuates the hypoxic depolarization, improving the recovery of neurons following hypoxia. Thus, sevoflurane acts via a metabotropic pathway to improve recovery following hypoxia.
麻醉预处理是指在缺氧或缺血性损伤前给予挥发性麻醉剂(如七氟醚),这已被证明可改善损伤后的神经元恢复。我们发现,七氟醚诱导的大鼠海马切片预处理增强了 CA1 锥体神经元的缺氧超极化,延迟并减轻其缺氧去极化,并增加了缺氧后恢复静息和动作电位的神经元数量。这些改变的电生理效应和改善的恢复与脑内一种组成型激活的非典型蛋白激酶 C 同工型(蛋白激酶 M ζ,PKMζ)的增加相对应。该激酶的选择性抑制剂,zeta 抑制肽(ZIP),阻断了 PKMζ 蛋白总量和该激酶激活形式磷酸化 PKMζ(p-PKMζ)的增加;它还阻断了改变的电生理效应和改善的恢复。我们发现,蛋白合成抑制剂环己酰亚胺和调节蛋白合成的 mTOR 通路的选择性抑制剂雷帕霉素均阻断了 p-PKMζ 的增加、电生理变化和七氟醚诱导的预处理所致的改善恢复。当仅在缺氧期间存在时,KATP 通道阻滞剂格列本脲可防止增强的超极化、延迟和减轻的缺氧去极化以及七氟醚诱导的预处理后的改善恢复。为了研究预处理建立后持续 PKMζ和 KATP 通道活性的功能,我们给予 4%七氟醚 30 分钟,然后在缺氧前 30 分钟停止给予七氟醚。当在七氟醚洗脱后至少 15 分钟给予甲苯磺丁脲(一种 KATP 通道阻滞剂)或 ZIP 时,与单独给予七氟醚相比,恢复很少。因此,需要持续的 KATP 通道和 PKMζ 活性来维持预处理保护。我们的结论是,七氟醚诱导 mTOR 通路的激活,增加 PKMζ 的新蛋白合成,使其组成性磷酸化至其活性形式,导致增加的 KATP 通道诱导的超极化。这种超极化延迟并减轻缺氧去极化,改善缺氧后神经元的恢复。因此,七氟醚通过代谢型途径作用于改善缺氧后的恢复。