钙蛋白酶通过降解突触蛋白Ⅰ介导脑出血后继发性神经元损伤

摘要/Abstract

摘要：

目的观察钙蛋白酶在实验性脑出血后继发性神经元损伤中的作用及其机制。方法脑内注射自体血液法制作小鼠脑出血模型，将10周龄雄性C57BL/6J小鼠实验动物随机分为4 组：0 h组（对照组）、2 h组、12 h组和24 h组，每组10只小鼠。收集血肿周围脑组织后检测血肿周围组织钙蛋白酶活性水平，免疫印迹法检测突触蛋白Ⅰ表达水平。重组的突触蛋白Ⅰ与钙蛋白酶共孵育后检测其降解过程，并观察钙蛋白酶抑制剂ALLN和MDL28170的作用。在体外培养的神经元样大鼠肾上腺嗜铬细胞瘤细胞（PC12细胞）中加入钙蛋白酶，观察其细胞损伤作用和对突触蛋白Ⅰ的降解。结果脑出血后2 h血肿周围脑组织钙蛋白酶活性升高，至24 h达到高峰。脑出血0 h、2 h、12 h和24 h 后钙蛋白酶活性读数分别为234.32、343.87、425.29和597.36，12 h组和24 h组与对照组相比差异具有显著性（P＜0.05）。同时突触蛋白Ⅰ水平逐渐降低，提示其降解。至血肿形成后24 h下降到对照组的67.00%（P＜0.01）。纯化的重组突触蛋白Ⅰ与钙蛋白酶共孵育后出现降解，孵育30 min后突触蛋白Ⅰ 含量下降至对照组（0 h组）的57.75%（P =0.001），在钙蛋白酶抑制剂ALLN（50 μmol/L）和MDL28170 （10 μmol/L）存在的情况下，突触蛋白Ⅰ水平分别为对照组的87.00%和84.75%（与单纯钙蛋白酶处理组30 min组相比，P＜0.05）。外源性钙蛋白酶与PC12细胞共孵育12 h后细胞活力下降到对照组的 58.25%（P＜0.01），而ALLN和MDL28170处理组细胞活力升高到对照组的83.00%和80.25%（与单纯钙蛋白酶处理组相比，P＜0.01）。结论钙蛋白酶通过降解突触蛋白Ⅰ参与脑出血后的继发性神经损伤，有可能成为脑出血的治疗靶点。

文章导读： 本文通过在体和离体模型的研究观察到钙蛋白酶通过降解其底物突触蛋白Ⅰ参与神经损伤的作用
及其机制，为脑出血后继发性神经损伤寻找新的治疗靶点提供依据。

关键词: 钙蛋白酶; 脑出血; 突触蛋白Ⅰ

Abstract:

Objective To investigate the role of calpain in secondary neuronal injury after intracerebral hemorrhage. Methods Experimental intracerebral hemorrhage (ICH) was induced in mice by intraparenchymal injection of autologous blood. The animals were randomly separated into 4 groups:0 h group (control group), 2 h group, 4 h group, and 24 h group. Each group contains 10 mice. The activity of calpain in the brain tissues were evaluated at different time points. The degradation of synapsin Ⅰ was analyzed by Western blot. The cleavage of recombinant synapsin Ⅰ was analyzed after incubation with active calpain. The effects of exogenous calpain and calpain inhibitors ALLN and MDL28170 on PC12 cells were analyzed by MTT assay. The expression of synapsin Ⅰ was determined by Western blot. Results The activity of calpain increased in a time-dependent manner, with peak activation at 24 h. 0 h, 2 h, 12 h, and 24 h after surgery, the calpain activity reading was 234.32, 343.87, 425.29, and 597.36, respectively. The calpain activity of 12 h group and 24 h group was significantly higher than the 0 h group (P <0.05). The expression of synapse-associated protein synapsin Ⅰ decreased as the activity of calpain increased, indicating synapsin Ⅰ might be cleaved by calpain. The protein level of synapsin Ⅰ decreased to 67% of the control group (P <0.01). To verify the cleavage of synapsin Ⅰ by calpain, purified recombinant synapsin Ⅰ was incubated with active calpain in vitro. Calpain induced the degradation of synapsin Ⅰ. Synapsin Ⅰ level decreased to 57.75% (P =0.001) of the control group after 30 min incubation. The in vitro cleavage of synapsin Ⅰ by calpain was inhibited by calpain inhibitors. The level of synuclein Ⅰ was 87.00% and 84.75% in the present of ALLN and MDL28170, respectively (P <0.05 compared to the calpain group). Exogenous calpain induced cell toxicity in neuronal differentiated PC12 cells. The cell viability decreased to 58.25% of the control group after 12 h incubation, In the presence of calpain inhibitors ALLN and MDL28107, the cell viability increased to 83.00% and 80.25%, respectively (P <0.01 compared to calpain group). Conclusion Calpain plays importan roles in the secondary neuronal injury after intracerebral hemorrhage by degradation synapsin Ⅰ. It is a potential therapeutic target for the treatment of intracerebral hemorrhage.

Key words: Calpain; Intracerebral hemorrhage; SynapsinⅠ

张振涛，张国新，王洪财，熊婧，胡丹，张兆辉. 钙蛋白酶通过降解突触蛋白Ⅰ介导脑出血后继发性神经元损伤[J]. 中国卒中杂志, 2014, 9(12): 993-998.

ZHANG Zhen-Tao*, ZHANG Guo-Xin, WANG Hong-Cai,XIONG Jing, HU Dan, ZHANG Zhao-Hui.. Calpain Induces Secondary Neuronal Injury after Intracerebral Hemorrhage via
Degradation of SynapsinⅠ[J]. Chinese Journal of Stroke, 2014, 9(12): 993-998.

参考文献

1 Gao C, Du H, Hua Y, et al. Role of red blood cell

lysis and iron in hydrocephalus after intraventricular hemorrhage[J]. J Cereb Blood Flow Metab, 2014,

34:1070-1075.

2 Lauer A, Pfeilschif ter W, Schaf fer CB, et al.

I nt r a c e r eb r a l h a emor r h a ge a s s o c i a t e d wi t h

antithrombotic treatment:translational insights

from experimental studies[J]. Lancet Neurol, 2013,

12:394-405.

3 Bernath E, Kupina N, Liu MC, et al. Elevation of

cytoskeletal protein breakdown in aged Wistar rat

brain[J]. Neurobiol Aging, 2006, 27:624-632.

4 Katayama J, Akaike N, Nabekura J. Characterization

of pre- and post-synaptic metabotropic glutamate

receptor-mediated inhibitory responses in substantia

nigra dopamine neurons[J]. Neurosci Res, 2003,

45:101-115.

5 Lee MS, Kwon YT, Li M, et al. Neurotoxicity induces

cleavage of p35 to p25 by calpain[J]. Nature, 2000,

405:360-364.

6 Krafft PR, Rolland WB, Duris K, et al. Modeling

int racerebral hemor rhage in mice:injection of

autologous blood or bacterial collagenase[J]. J Vis

Exp, 2012:e4289.

7 Xi G, Keep RF, Hoff JT. Mechanisms of brain injury

after intracerebral haemorrhage[J]. Lancet Neurol,

2006, 5:53-63.

8 Belu r PK, Ch a ng J J, He S, e t a l . Eme rg i ng

experimental therapies for intracerebral hemorrhage:

targeting mechanisms of secondary brain injury[J].

Neurosurg Focus, 2013, 34:E9.

9 Zheng M, Gong Y, Wang X, et al. Alteration of

intracellular calcium and its modulator SLC24A6

after experimental intracerebral hemorrhage[J]. Acta

Neurochir Suppl, 2013, 118:169-173.

10 Rami A, Krieglstein J. Protective effects of calpain

inhibitors against neuronal damage caused by

cytotoxic hypoxia in vitro and ischemia in vivo[J].

Brain Res, 1993, 609:67-70.

11 Ono Y, Sor ima chi H. Calpa i ns:An elabor at e

proteolytic system[J]. Biochim Biophys Acta, 2012,

1824:224-236.

12 Storr SJ, Carragher NO, Frame MC, et al. The calpain system and cancer[J]. Nat Rev Cancer, 2011, 11:364-

374.

13 Amini M, Ma CL, Farazifard R, et al. Conditional

disruption of calpain in the CNS alters dendrite

morphology, impairs LTP, and promotes neuronal

survival following injury[J]. J Neurosci, 2013,

33:5773-5784.

14 Moldoveanu T, Hosfield CM, Lim D, et al. A Ca(2+)

switch aligns the active site of calpain[J]. Cell, 2002,

108:649-660.

15 Cesca F, Baldelli P, Valtorta F, et al. The synapsins:key

actors of synapse function and plasticity[J]. Prog

Neurobiol, 2010, 91:313-348.

16 Rosahl TW, Spillane D, Missler M, et al. Essential

functions of synapsins I and II in synaptic vesicle

regulation[J]. Nature, 1995, 375:488-943.

17 Murrey HE, Gama CI, Kalovidouris SA, et al. Protein

fucosylation regulates synapsin Ia/Ib expression

and neuronal morphology in primary hippocampal

neurons[J]. Proc Natl Acad Sci U S A, 2006, 103:21-

26.

18 Gitler D, Xu Y, Kao HT, et al. Molecular determinants

of synapsin targeting to presynaptic terminals[J]. J

Neurosci, 2004, 24:3711-3720.

19 Orlando M, Lignani G, Maragliano L, et al. Functional

role of ATP binding to synapsin I in synaptic vesicle

trafficking and release dynamics[J]. J Neurosci, 2014,

34:14752-14768.

20 Chi P, Greengard P, Ryan TA. Synaptic vesicle

mobilization is regulated by distinct synapsin I

phosphorylation pathways at different frequencies[J].

Neuron, 2003, 38:69-78.

21 Chen TI, Chiu HW, Pan YC, et al. Intermittent

hypoxia-induced protein phosphatase 2A activation

reduces PC12 cell proliferation and differentiation[J].

J Biomed Sci, 2014, 21:46.

22 J a nt a s D, Lo r e n c -Ko c i E, Ku b e r a M, e t a l .

Neuroprotective effects of MAPK/ERK1/2 and

calpain inhibitors on lactacystin-induced cell damage

in primary cortical neurons[J]. Neurotoxicology, 2011,

32:845-856.

[1]	郑占军, 赵性泉. 脑小血管病影像学标志物与自发性高血压脑出血的相关性研究进展[J]. 中国卒中杂志, 2022, 17(12): 1396-1402.
[2]	程实, 李静, 郭军平, 胡爱香, 于鑫玮, 韩玮, 梁瑛, 张越巍, 冀瑞俊. 急性卒中患者住院期间感染的临床特征及危险因素分析[J]. 中国卒中杂志, 2022, 17(10): 1065-1070.
[3]	范琳琳, 田飞. 以癫痫持续状态和脑出血为特征的胶质母细胞瘤1例并文献复习[J]. 中国卒中杂志, 2022, 17(09): 1002-1006.
[4]	王拥军, 李子孝, 谷鸿秋, 翟屹, 姜勇, 周齐, 赵性泉, 王伊龙, 杨昕, 王春娟, 孟霞, 李昊, 刘丽萍, 荆京, 吴静, 徐安定, 董强, David Wang, 王文志, 马旭东, 赵继宗, 《中国卒中报告》编写委员会（第一作者）. 中国卒中报告2020（中文版）（3）[J]. 中国卒中杂志, 2022, 17(07): 675-682.
[5]	宋新杰, 姜睿璇, 张怡君, 王安心, 李子孝, 赵性泉. 脑出血急性期不同血压参数与预后的关系[J]. 中国卒中杂志, 2022, 17(07): 769-773.
[6]	王拥军, 李子孝, 谷鸿秋, 翟屹, 姜勇, 周齐, 赵性泉, 王伊龙, 杨昕, 王春娟, 孟霞, 李昊, 刘丽萍, 荆京, 吴静, 徐安定, 董强, David Wang, 王文志, 马旭东, 赵继宗, 《中国卒中报告》编写委员会（第一作者）. 中国卒中报告2020（中文版）（2）[J]. 中国卒中杂志, 2022, 17(06): 553-567.
[7]	宋新杰, 王安心, 李子孝, 赵性泉. 下肢深静脉血栓形成与脑出血患者预后的关系研究[J]. 中国卒中杂志, 2022, 17(06): 634-637.
[8]	王拥军, 李子孝, 谷鸿秋, 翟屹, 姜勇, 周齐, 赵性泉, 王伊龙, 杨昕, 王春娟, 孟霞, 李昊, 刘丽萍, 荆京, 吴静, 徐安定, 董强, David Wang, 王文志, 马旭东, 赵继宗, 《中国卒中报告》编写委员会（第一作者）. 中国卒中报告2020（中文版）（1）[J]. 中国卒中杂志, 2022, 17(05): 433-447.
[9]	刘欣瑶, 毕京凤, 张英魁. 脑出血信号改变机制与磁共振影像表现[J]. 中国卒中杂志, 2021, 16(12): 1217-1221.
[10]	冯皓, 王鑫, 王文娟, 赵性泉. 不同性别老年脑出血患者血脂水平与预后的关系研究[J]. 中国卒中杂志, 2021, 16(10): 1016-1022.
[11]	陈晴晴, 孙金菊, 周雪姣. 急性脑出血继发院内消化道出血的影响因素分析[J]. 中国卒中杂志, 2021, 16(10): 1029-1033.
[12]	徐昳, 陈淑芬, 韩翔. 感染性心内膜炎合并脑出血伴多器官梗死1例[J]. 中国卒中杂志, 2021, 16(08): 774-778.
[13]	王丹丹, 王晶, 王安心, 张怡君, 赵性泉. 超敏C反应蛋白与新发脑出血关系研究[J]. 中国卒中杂志, 2021, 16(07): 664-669.
[14]	王振, 徐伟, 贺国华, 胡珏, 冯铁桥, 童洋萍, 徐桂兰, 肖慧, 易海波, 宋治. 急性缺血性卒中静脉溶栓后远隔部位脑出血的临床特征和预后分析[J]. 中国卒中杂志, 2021, 16(07): 680-686.
[15]	常贺生, 张贵涛, 王誉博, 于淼欣, 王晓宇, 徐娟玉, 邓亚仙, 刘改芬, 赵成松, 秦选光. 儿童脑出血患者住院期间脑积水危险因素研究[J]. 中国卒中杂志, 2021, 16(06): 581-584.