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研究生: 鄭勤巧
TEE QIN QIAO
論文名稱: 咖啡酸預防高胰島素血症大鼠阿茲海默症之機制
Preventive mechanism of caffeic acid against Alzheimer's disease in hyperinsulinemic rats
指導教授: 沈賜川
Shen, Szu-Chuan
吳瑞碧
Wu, Swi-Bea
學位類別: 碩士
Master
系所名稱: 人類發展與家庭學系
Department of Human Development and Family Studies
論文出版年: 2014
畢業學年度: 102
語文別: 中文
論文頁數: 134
中文關鍵詞: 咖啡酸高胰島素血症阿茲海默症
英文關鍵詞: caffeic acid, hyperinsulinemic, Alzheimer's disease
論文種類: 學術論文
相關次數: 點閱:155下載:6
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  • 高脂飲食易促使肥胖、周邊胰島素阻抗及糖尿病等疾病進程,接續造成腦部胰島素阻抗而最終導致阿茲海默症(Alzheimer’s disease, AD)的發生。流行病學研究顯示,第二型糖尿病病患罹患阿茲海默症的機率較正常人高出兩到三倍。本實驗室先前以胰島素阻抗細胞模式篩選出本實驗樣品--咖啡酸(caffeic acid),且在動物實驗中發現其具有改善腦部醣類代謝及胰島素訊息傳遞的效果。因此,本研究進一步探討咖啡酸可否預防以高脂飲食(脂質佔總熱量60%)誘導高胰島素血症大鼠阿茲海默症的發生,並釐清其機制。
    水迷宮試驗結果顯示,合併管餵咖啡酸(30mg/ kg b.w.) 30週後可顯著改善高胰島素血症大鼠的學習及記憶能力;在抗氧化系統中,咖啡酸可預防高脂飲食所造成的海馬迴及大腦皮質超氧岐化酶 (superoxide dismutase, SOD) 失活,並可增加大腦皮質麩胱甘肽 (glutathione) 捕捉自由基的能力;以西方點墨法分析發現,咖啡酸可增加高胰島素血症大鼠海馬迴胰島素訊息傳遞下游路徑蛋白:蛋白激酶B (p-AKT/PKB)、磷酸化肝醣合成酶 (phospho-glycogen synthase 3β, p-GSK3β) 的表現量,以降低tau蛋白的過度磷酸化。此外,咖啡酸可降低海馬迴類澱粉蛋白前驅物 (amyloid protein precursor, APP)及APP β部位切割酵素 (β-site APP cleaving enzyme, BACE) 的表現量,進而減少海馬迴中類澱粉蛋白1-42 (β-amyloid 1-42, Aβ 1-42) 的堆積。在大腦皮質部分,咖啡酸可提高具有神經保護功效的腦源性神經滋養因子 (brain-derived neurotrophic factor, BDNF) 及突觸相關蛋白的表現,且有助於降低胰島素降解酵素 (insulin degrading enzyme, IDE) 因代償作用的過量表現。
    由以上結果推測,咖啡酸可透過改善胰島素/瘦體素訊息傳遞、降低神經細胞氧化壓力、減少tau蛋白過度磷酸化、阻斷類澱粉蛋白生成及增加神經滋養因子等神經保護機制,以有效預防阿茲海默症的發生。

    High fat-diet (HFD) promotes obesity, increases the risk of insulin resistance and diabetes mellitus (DM). It also contributes to brain insulin resistance and the pathogenesis of Alzheimer’s disease (AD). Epidemiologically, patients with Type 2 DM have a two-to three-fold increased risk for AD. We previously confirmed caffeic acid improves glucose metabolism and alleviates insulin resistance in cell and animal models. In this study, we further investigate the alleviative effect of caffeic acid on AD pathogenesis and associated mechanisms in HFD (60% fat) induced hyperinsulinemic rats.
    According to the results of Morris water maze, caffeic acid (30mg/ kg b.w./ day) significantly ameliorated memory and learning impairment in hyperinsulinemic rats. Caffeic acid enhanced superoxide dismutase (SOD) activity and the glutathione free radical scavenger activity in hyperinsulinemic rats. The results from western blotting shows that protein expressions of p-AKT/Protein kinase B (p-AKT/ PKB), p-glycogen synthase kinase3β (p-GSK3β) significantly increased, whereas, the expression of p-tau decreased in hippocampus of rats administered with caffeic acid compared with the hyperinsulinemic control group. Besides, the expression of amyloid precursor protein (APP) and β-site APP cleaving enzyme (BACE) were attenuated in the hippocampus of hyperinsulinemic rats treated with caffeic acid, therefore lowered the level of β-amyloid 1-42(Aβ 1-42). Experimentally, caffeic acid increased the expressions of brain-derived neurotrophic factor (BDNF) and synaptic protein in the cortex compared with the hyperinsulinemic control group. Compensatory effect of insulin degrading ezyme (IDE) in hyperinsulinemic rats was also reduced by the administration of caffeic acid.
    Above observation suggests that caffeic acid may exhibit the neuroprotective effect via improves insulin/leptin signaling, decreases oxidative stress, attenuates the hyperphosphorylation of tau protein and amyloidgenic pathway, and upregulates the expression of neurotrophic factor, thus may prevent the pathogenesis of AD.

    中文摘要 I Abstract II 目錄 IV 圖次 VII 表次 X 第一章 前言 1 第二章 文獻回顧 3 第一節 胰島素阻抗 3 一、 高脂飲食與胰島素阻抗 3 二、 腦部胰島素阻抗 5 第二節 阿茲海默症(Alzheimer’s disease; AD)7 一、 阿茲海默症流行病學 7 二、 阿茲海默症的分類 8 三、 阿茲海默症病理機轉 8 四、 阿茲海默症疾病進程 10 五、 阿茲海默症治療方式 12 第三節 阿茲海默症與第二型糖尿病 14 一、 阿茲海默症與第二型糖尿病相關研究 14 二、 阿茲海默症與第二型糖尿病共同致病因子 14 第四節 阿茲海默症發生的路徑蛋白表現 20 一、 腦部胰島素訊息傳遞途徑 20 二、 腦部類澱粉蛋白生成途徑 21 三、 腦部神經纖維糾結生成路徑 24 四、 腦部類澱粉蛋白降解路徑 26 五、 腦部神經滋養因子 27 第五節 誘發阿茲海默症之實驗動物模式探討 29 一、 實驗動物腦部注射類澱粉蛋白之阿茲海默症模式 29 二、 基因轉殖老鼠之阿茲海默症模式 29 三、 飲食內容調整間接誘發阿茲海默症模式 30 第六節 Thiazolidinediones (TZD) 藥物 Pioglitazone 31 一、 Pioglitazone與第二型糖尿病糖尿病 31 二、 Pioglitazone與學習記憶能力 32 第七節 酚酸與阿茲海默症 33 一、 天然酚酸 33 二、 咖啡酸(Caffeic acid) 33 三、 咖啡酸與阿茲海默症之相關研究 34 第三章 研究動機與目的及實驗架構 35 第一節 研究動機與目的 35 第二節 實驗架構 36 第四章 實驗材料與方法 37 第一節 實驗材料 37 第二節 實驗步驟與方法 41 第五章 結果 55 第一節 咖啡酸對高胰島素血症大鼠學習及記憶能力的影響 55 一、 水迷宮試驗 55 第二節 咖啡酸對高胰島素血症大鼠腦部病理切片之影響 62 一、 腦部切片蘇木紫與伊紅染色(Hematoxylin and Eosinstain, H&E stain)分析 62 第三節 咖啡酸對高胰島素血症大鼠海馬迴及皮質抗氧化酵素活性之影響 65 一、 咖啡酸對高胰島素血症大鼠海馬迴及皮質超氧岐化酶(SOD)表現之影響 65 二、 咖啡酸對高胰島素血症大鼠海馬迴及皮質過氧化氫酶(catalase)活性之影響 65 三、 咖啡酸對高胰島素血症大鼠海馬迴及皮質氧化態麩胱甘肽(GSSG)與總麩胱甘肽(total GSH)比值之影響 66 第四節 咖啡酸對高胰島素血症大鼠海馬迴及皮質發炎因子之影響 70 一、 咖啡酸對高胰島素血症大鼠海馬迴及皮質介白素-6 (IL-6)表現量之影響 70 二、 咖啡酸對高胰島素血症大鼠海馬迴及皮質腫瘤壞死因子α (TNF-α)表現量之影響 70 第五節 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質類澱粉蛋白表現之影響73 第六節 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質蛋白質表現之影響 75 一、 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質Tau蛋白磷酸化路徑蛋白質表現之影響 75 二、 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質類澱粉蛋白生成路徑蛋白質表現之影響 82 三、 咖啡酸對高胰島素血症大鼠海馬迴及皮質類澱粉蛋白降解路徑蛋白質表現之影響 90 四、 咖啡酸對高胰島素血症大鼠海馬迴及皮質神經可塑性相關蛋白質表現之影響 92 第六章 討論 98 第一節 咖啡酸對高胰島素血症大鼠學習及記憶能力的影響 98 第二節 咖啡酸對高胰島素血症大鼠腦部病理切片之影響 100 第三節 咖啡酸對高胰島素血症大鼠海馬迴及皮質抗氧化活性之影響 101 第四節 咖啡酸對高胰島素血症大鼠海馬迴及皮質發炎因子之影響 103 第五節 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質蛋白質表現之影響 104 一、 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質Tau蛋白磷酸化路徑蛋白質表現之影響 104 二、 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質類澱粉蛋白生成路徑蛋白質表現之影響 106 三、 咖啡酸對高胰島素血症大鼠海馬迴及大腦皮質類澱粉蛋白降解路徑蛋白質表現之影響 108 四、 咖啡酸對高胰島素血症大鼠海馬迴及皮質神經可塑性相關蛋白質表現之影響 109 第七章 結論 111 第八章 參考文獻 114 第九章 附錄 127 第一節 咖啡酸對高胰島素血症大鼠攝食飲水量及生長狀況之影響 127 第二節 咖啡酸對高胰島素血症大鼠血糖及血清荷爾蒙濃度之影響 130 第三節 咖啡酸對高胰島素血症大鼠被動迴避試驗的影響 134

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