Kim Jong Youl, Kim Nuri, Zheng Zhen, Lee Jong Eun, Yenari Midori A
From the Department of Neurology, UCSF and the SF Veterans Affairs Medical Center, CA (J.Y.K., N.K., Z.Z., M.A.Y.); and Department of Anatomy, BK21 Plus Project for Medical Science and Brain Research Institute, Yonsei University College of Medicine, Seoul, ROK (J.E.L.).
Stroke. 2016 Aug;47(8):2103-11. doi: 10.1161/STROKEAHA.116.012763. Epub 2016 Jul 7.
The 70-kDa heat shock protein (Hsp70) protects brain cells in models of cerebral ischemia. Proteomic screening of mice subjected to middle cerebral artery occlusion identified dynamin as a major downregulated protein in Hsp70-overexpressing mice (Hsp70 transgenic mice). Dynamin-1 is expressed in neurons and participates in neurotransmission, but also transports the death receptor Fas to the cell surface, where it can be bound by its ligand and lead to apoptosis.
Mice were subjected to distal middle cerebral artery occlusion. Neuro-2a cells were subjected to oxygen glucose deprivation. Hsp70 transgenic and Hsp70-deficient (Hsp70 knockout) mice were compared with wild-type mice for histological and behavioral outcomes. Some mice and neuro-2a cell cultures were given dynasore, a dynamin inhibitor.
Hsp70 transgenic mice had better outcomes, whereas Hsp70 knockout mice had worse outcomes compared with wild-type mice. This correlated with decreased and increased dynamin expression, respectively. Dynamin colocalized to neurons and Fas, with higher Fas levels and increased caspase-8 expression. Hsp70 induction in neuro-2a cells was protected from oxygen glucose deprivation, while downregulating dynamin and Fas expression. Further, dynamin inhibition was found to be neuroprotective.
Dynamin may facilitate Fas-mediated apoptotic death in the brain, and Hsp70 may protect by preventing this trafficking. Dynamin should be explored as a new therapeutic target for neuroprotection.
70 kDa热休克蛋白(Hsp70)在脑缺血模型中可保护脑细胞。对大脑中动脉闭塞小鼠进行蛋白质组学筛查发现,发动蛋白是Hsp70过表达小鼠(Hsp70转基因小鼠)中一种主要下调的蛋白质。发动蛋白-1在神经元中表达并参与神经传递,还将死亡受体Fas转运至细胞表面,在那里它可被其配体结合并导致细胞凋亡。
对小鼠进行大脑中动脉远端闭塞。对Neuro-2a细胞进行氧糖剥夺。将Hsp70转基因和Hsp70缺陷(Hsp70基因敲除)小鼠与野生型小鼠进行组织学和行为学结果比较。给一些小鼠和Neuro-2a细胞培养物使用发动蛋白抑制剂dynasore。
与野生型小鼠相比,Hsp70转基因小鼠的结果更好,而Hsp70基因敲除小鼠的结果更差。这分别与发动蛋白表达的降低和增加相关。发动蛋白与神经元和Fas共定位,Fas水平更高且半胱天冬酶-8表达增加。Neuro-2a细胞中Hsp70的诱导可免受氧糖剥夺的影响,同时下调发动蛋白和Fas的表达。此外,发现抑制发动蛋白具有神经保护作用。
发动蛋白可能促进大脑中Fas介导的凋亡性死亡,而Hsp70可能通过阻止这种转运来发挥保护作用。应将发动蛋白作为神经保护的新治疗靶点进行探索。