[1]夏天光,刁云锋,毕 莹,等.糖化β-淀粉样蛋白对阿尔茨海默病样大鼠认知功能的影响[J].新乡医学院学报,2019,36(6):511-516.[doi:10.7683/xxyxyxb.2019.06.003]
 XIA Tian-guang,DIAO Yun-feng,BI Ying,et al.Effect of glycated β-amyloid protein on cognitive function of Alzheimer′s disease-like rats[J].Journal of Xinxiang Medical University,2019,36(6):511-516.[doi:10.7683/xxyxyxb.2019.06.003]
点击复制

糖化β-淀粉样蛋白对阿尔茨海默病样大鼠认知功能的影响
分享到:

《新乡医学院学报》[ISSN:1004-7239/CN:41-1186/R]

卷:
36
期数:
2019年6
页码:
511-516
栏目:
基础研究
出版日期:
2019-06-05

文章信息/Info

Title:
Effect of glycated β-amyloid protein on cognitive function of Alzheimer′s disease-like rats
作者:
夏天光刁云锋毕 莹张 健陈江龙董化江董月青
(武警后勤学院附属医院脑创伤与神经疾病研究所,天津 300162)
Author(s):
XIA Tian-guangDIAO Yun-fengBI YingZHANG JianCHEN Jiang-longDONG Hua-jiangDONG Yue-qing
(Institute of Brain Trauma and Neurology,Affiliated Hospital of Logistics University of Chinese People′s Armed Police Forces,Tianjin 300162,China)
关键词:
阿尔兹海默病β-淀粉样蛋白糖基化晚期糖基化终产物受体
Keywords:
Alzheimer′s diseaseβ-amyloidglycationreceptor of advanced glycation endproducts
分类号:
R742
DOI:
10.7683/xxyxyxb.2019.06.003
文献标志码:
A
摘要:
目的 探讨糖化β-淀粉样蛋白(Aβ-AGE)对阿尔茨海默病样大鼠认知功能的影响。方法 将β-淀粉样蛋白(Aβ)与甲基乙二醛于37 ℃下温育1个月合成Aβ-AGE。将40只Sprague Dawley大鼠随机分为Aβ组、Aβ+小鼠单克隆高级糖化终产物受体抗体(Anti-RAGE)组、Aβ-AGE组、Aβ-AGE+Anti-RAGE组,每组10只。行立体定向左侧侧脑室注射制备阿尔茨海默病样模型,其中Aβ组大鼠给予Aβ 5 μg,Aβ+Anti-RAGE组大鼠给予Aβ 5 μg 和 RAGE抗体 Anti-RAGE 50 μg,Aβ-AGE组大鼠给予Aβ-AGE 5 μg,Aβ-AGE+Anti-RAGE组大鼠给予Aβ-AGE 5 μg和Anti-RAGE 50 μg。注射后第2~7天进行Morris水迷宫实验,记录大鼠寻找隐匿平台的潜伏期;注射后第9天,记录各组大鼠穿越平台次数和目标象限停留时间;Western blot法检测各组大鼠海马组织中高级糖化终产物受体(RAGE)蛋白的表达,免疫组织化学染色法检测各组大鼠大脑皮层中RAGE的表达。结果 在注射后第2天,各组大鼠潜伏期比较差异无统计学意义(F=3.767,P>0.05)。注射后第3~7天,各组大鼠潜伏期比较差异均有统计学意义(F=9.167、25.050、56.980、62.380、122.200,P<0.05);Aβ-AGE组大鼠潜伏期显著长于Aβ组(P<0.05),Aβ+Anti-RAGE组大鼠潜伏期显著短于Aβ组(P<0.05),Aβ-AGE+Anti-RAGE组大鼠潜伏期显著短于Aβ-AGE组(P<0.05)。注射后第9天,各组大鼠穿越平台次数和目标象限停留时间比较差异有统计学意义(F=12.930、13.560,P<0.05);Aβ-AGE组大鼠穿越平台次数和目标象限停留时间显著短于Aβ组(P<0.05),Aβ+Anti-RAGE组大鼠穿越平台次数和目标象限停留时间显著长于Aβ组(P<0.05),Aβ-AGE+Anti-RAGE组大鼠穿越平台次数和目标象限停留时间显著长于Aβ-AGE组(P<0.05)。注射后第9天,各组大鼠海马组织中RAGE蛋白相对表达量比较差异有统计学意义(F=8.626,P<0.05);Aβ-AGE组大鼠海马组织中RAGE蛋白相对表达量显著高于Aβ组(P<0.05),Aβ+Anti-RAGE组大鼠海马组织中RAGE蛋白相对表达量与Aβ组比较差异无统计学意义(P>0.05),Aβ-AGE+Anti-RAGE组大鼠海马组织中RAGE蛋白相对表达量显著低于Aβ-AGE组(P<0.05)。免疫组织化学染色结果显示,各组大鼠大脑皮层中RAGE阳性细胞数比较差异有统计学意义(F=76.370、P<0.01);Aβ-AGE组大鼠大脑皮层中RAGE阳性细胞数显著高于Aβ组(P<0.01),Aβ+Anti-RAGE组大鼠皮层中RAGE阳性细胞数显著低于Aβ组(P<0.01);Aβ-AGE+Anti-RAGE组大鼠皮层中RAGE阳性细胞数显著低于Aβ-AGE组(P<0.01)。结论 Aβ-AGE可能通过激活RAGE信号转导通路介导加重AD样大鼠的认知功能障碍,Aβ-AGE和RAGE可能成为治疗AD的新靶点。
Abstract:
Objective To investigate the effect of glycated amyloid β (Aβ-AGE) on cognitive function of Alzheimer′s disease-like rats.Methods Aβ-AGE was synthesized by incubating with methylglyoxal under 37 ℃ for 1 month.Forty Sprague Dawley(SD) rats were randomly divided into Aβ group,Aβ+ mouse monoclonal advanced glycation end product receptor antibody (Anti-RAGE) group,Aβ-AGE group,Aβ-AGE+Anti-RAGE group,with 10 rats in each group.The Aβ(5 μg) were stereotaxically injected into the lateral ventricle of rats in Aβ group,the Aβ(5 μg) and Anti-RAGE(50 μg) were stereotaxically injected into the lateral ventricle of rats in Aβ+Anti-RAGE group,the Aβ-AGE(5 μg) were stereotaxically injected into the lateral ventricle of rats in Aβ-AGE group,the Aβ-AGE(5 μg) and Anti-RAGE(50 μg) were stereotaxically injected into the lateral ventricle of rats in Aβ-AGE+ Anti-RAGE group.Morris water maze test was performed on the 2-7 days after administration to detect the latency of rats for searching the hidden platform.The number of crossing platform and the time stayed in the target quadrant of rats were detected on the ninth day after administration.The expression of receptor for advanced glycation endproducts (RAGE) protein in hippocampus of rats were examined by Western blot.The expression of RAGE in the cortex of rats in each group was detected by immunohistochemistry.Results There was no significant difference in the latency period of rats among the groups on the second day after administration (F=3.767,P>0.05).There was statistic difference in the latency period of rats in each group on the 3-7 day after administration (F=9.167,25.050,56.980,62.380,122.200;P<0.05);the latency period of rats in the Aβ-AGE group was significantly longer than that in the Aβ group (P<0.05);the latency period of rats in the Aβ+Anti-RAGE group was significantly shorter than that in the Aβ group (P<0.05);the latency period of rats in the Aβ-AGE+Anti-RAGE group was significantly shorter than that in the Aβ-AGE group (P<0.05).There was significant difference in the number of crossing the platform and the time stayed in the target quadrant of rats among the groups on the ninth day after administration (F=12.930,13.560;P<0.05).The number of crossing the platform and the time stayed in the target quadrant of rats in Aβ-AGE group were significantly lower than those in the Aβ group (P<0.05);in the Aβ+Anti-RAGE group the number of crossing the platform was more and the time stayed in the target quadrant of rats was loger than those in the Aβ group (P<0.05);in the Aβ-AGE+Anti-RAGE group the number of crossing the platform was more and the time stayed in the target quadrant of rats was longer than those in the Aβ-AGE group (P<0.05).There was statistic difference in the relative expression of RAGE protein in hippocampus of rats among the groups on the ninth day after administration (F=8.626,P<0.05).The relative expression of RAGE protein in hippocampus of rats in the Aβ-AGE group was significantly higher than that in the Aβ group (P<0.05);there was no statistic difference in the relative expression of RAGE protein in hippocampus of rats between the Aβ+Anti-RAGE group and Aβ group (P>0.05);the relative expression of RAGE protein in hippocampus of rats in the Aβ-AGE+Anti-RAGE group was significantly lower than that in the Aβ-AGE group (P<0.05).Immunohistochemical staining results showed that there was statistic difference in the number of RAGE positive cells in the cerebral cortex of rats among the groups (F=76.370,P<0.01).The number of RAGE positive cells in the cerebral cortex of rats in the Aβ-AGE group was significantly more than that in the Aβ group (P<0.01);the number of RAGE positive cells in the cortex of rats in the Aβ+Anti-RAGE group was significantly less than that in the Aβ group (P<0.01);the number of RAGE positive cells in the cortex of rats in the Aβ-AGE+Anti-RAGE group was significantly less than that in the Aβ-AGE group(P<0.01).Conclusion Aβ-AGE may aggravate cognitive dysfunction of AD-like rats through activating RAGE pathway.The Aβ-AGE and RAGE may be new therapeutic targets for AD.

参考文献/References:

[1] LI K,WEI Q,LIU F F,et al.Synaptic dysfunction in Alzheimer′s disease:Aβ,Tau,and epigenetic alterations[J].Mol Neurobiol,2018,55(4):3021-3032.
[2] FAWVER J N,SCHALL H E,PETROFES C R D,et al.Amyloid-β metabolite sensing:biochemical linking of glycation modification and misfolding[J].J Alzheimers Dis,2012,30(1):63-73.
[3] DRENTH H,ZUIDENA S U,KRIJNEN W P,et al.Association between advanced glycation end-products and functional performance in Alzheimer′s disease and mixed dementia[J].Int Psychogeriatr,2017,29(9):1525-1534.
[4] ZHANG J,GUO Y,WANG Y,et al.Long-term treadmill exercise attenuates Aβ burdens and astrocyte activation in APP/PS1 mouse model of Alzheimer′s disease[J].Neurosci Let,2018,666:70-77.
[5] TAKUMA K,FANG F,ZHANG W,et al.RAGE-mediated signaling contributes to intraneuronal transport of amyloid-beta and neuronal dysfunction[J].Proc Natl Acad Sci USA,2009,106(47):20021-20026.
[6] CHEN C,LI X H,TU Y,et al.Aβ-AGE aggravates cognitive deficit in rats via RAGE pathway[J].Neuroscience,2014,257:1-10.
[7] FREDERIKSEN K S,GJERUM L,WALDEMAR G,et al.Effects of physical exercise on Alzheimer′s disease biomarkers:a systematic review of intervention studies[J].J Alzheimers Dis,2018,61(1):359-372.
[8] 王晓燕.血清胱抑素C、β2-微球蛋白、视黄醇结合蛋白、尿微量白蛋白及N-乙酰-β-D-氨基葡萄糖苷酶在诊断糖尿病早期肾损伤中的临床意义[J].新乡医学院学报,2017,34(2):143-146.
[9] TSUTSUI Y,HAYS F A.A link between Alzheimer′s and type II diabetes mellitus? Ca2+-mediated signal control and protein localization[J].Bioessays,2018,40(6):e1700219.
[10] KAMYNINA A V,ESTERAS N,KOROEV D O,et al.Synthetic fragments of receptor for advanced glycation end products bind beta-amyloid 1-40 and protect primary brain cells from beta-amyloid toxicity[J].Front Neurosci,2018,12:681.
[11] 张英博,费洪新,郭家,等.蝙蝠葛碱对阿尔茨海默病小鼠海马晚期糖基化终产物受体和核转录因子-κBp65的影响[J].中国老年学杂志,2017,37(19):4697-4700.
[12] VOLPINA O M,SAMOKHIN A N,KOROEV D O,et al.Synthetic fragment of receptor for advanced glycation end products prevents memory loss and protects brain neurons in olfactory bulbectomized mice[J].J Alzheimers Dis,2018,61(3):1061-1076.
[13] LI X H,DU L L,CHENG X S,et al.Glycation exacerbates the neuronal toxicity of β-amyloid[J].Cell Death Dis,2013,4:e673.
[14] STEUCHER E,GALICHET A,WEIBEL M,et al.Site-specific blockade of RAGE-Vd prevents amyloid-beta oligomer neurotoxicity[J].J Neurosci,2008,28(20):5149-5158.
[15] CAI Z,LIU N,WANG C,et al.Role of RAGE in Alzheimer′s disease[J].Cell Mol Neurobiol,2016,36(4):483-495.
[16] CHEN W,CHAN Y,WAN W,et al.Aβ1-42 induces cell damage via RAGE-dependent endoplasmic reticulum stress in bEnd.3 cells[J].Exp Cell Res,2018,362(1):83-89.

相似文献/References:

[1]张煜,张斌,翟溯澜,等.β-淀粉样蛋白对铝中毒大鼠脑海马神经元的影响 [J].新乡医学院学报,2006,23(03):000.
[2]韩永凯,王旭生,张 帆,等. 美金刚联合小剂量奥氮平治疗阿尔兹海默病伴有行为和精神症状患者临床研究[J].新乡医学院学报,2015,32(08):749.
[3]陈广田,曹兰秀.中医临床治疗阿尔兹海默病研究进展[J].新乡医学院学报,2021,38(6):593.[doi:10.7683/xxyxyxb.2021.06.021]
[4]郭珂一,周峥宇,赵幸娟.葛根素对阿尔茨海默病果蝇的神经保护作用及机制[J].新乡医学院学报,2022,39(6):513.[doi:10.7683/xxyxyxb.2022.06.003]
 GUO Keyi,ZHOU Zhengyu,ZHAO Xingjuan.Neuroprotective effect and mechanism of puerarin on drosophila with Alzheimer′s disease[J].Journal of Xinxiang Medical University,2022,39(6):513.[doi:10.7683/xxyxyxb.2022.06.003]

更新日期/Last Update: 2019-06-05