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研究生: 林品妤
Lin, Pin-Yu
論文名稱: Lunasin處理對餵食高脂飲食之C57BL/6J小鼠代謝異常之影響
The effects of lunasin on abnormal metabolism in high-fat diet-induced obese C57BL/6J mice
指導教授: 謝佳倩
Hsieh, Chia-Chien
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: 2019
畢業學年度: 107
語文別: 中文
論文頁數: 84
中文關鍵詞: Lunasin肥胖葡萄糖耐受性代謝異常
英文關鍵詞: Lunasin, Obesity, Glucose tolerance, Metabolic disorder
DOI URL: http://doi.org/10.6345/NTNU201900951
論文種類: 學術論文
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根據流行病學調查,全球肥胖人口日益增多,而肥胖與許多疾病之發生相關。肥胖會影響血糖、血脂與血壓等變化,長期會造成血液生化值異常及胰島素阻抗等現象,為代謝症候群之危險因子。種子胜肽lunasin經研究證實具有抗腫瘤、抗發炎、抗氧化及降膽固醇等生理功能。本研究目的為探討lunasin處裡對飲食誘發肥胖C57BL/6J公鼠之血液生化值、血清與肝臟小分子代謝體的影響;及對C2C12小鼠骨骼肌細胞葡萄糖代謝與胰島素敏感性之影響。第一部分動物實驗共分低脂飲食組 (low fat diet, LF)、高脂飲食組 (high fat diet, HF)、高脂飲食加腹腔注射4及20 mg/kg bw/day lunasin組 (HF+low dose lunasin, HF-LL及HF+high dose lunasin, HF-HL)以及高脂飲食添加富含lunasin之大豆蛋白組 (HF+ lunasin dietary intake, HF-DL)。結果發現,HF-HL組及HF-DL組顯著減緩肥胖小鼠葡萄糖耐受性異常之情形,且HF-HL組有降低血清三酸甘油酯之趨勢。然而lunasin處理對小鼠血糖、胰島素、血脂及肝臟脂質過氧化物則無顯著影響。另外,血液與肝臟小分子代謝體分析結果,HF組相較於LF組,克式循環和糖解作用中間產物及嘌呤代謝終產物uric acid顯著增加,且膽酸合成及膽固醇代謝相關及參與胺基酸代謝等小分子顯著下降。而lunasin處理能調節肥胖小鼠肝臟TCA cycle和糖解作用之中間產物及uric acid異常增加之情形,亦可改善肥胖小鼠血清及肝臟中參與胺基酸代謝之小分子下降之現象。第二部分細胞實驗探討lunasin介入對C2C12小鼠骨骼肌細胞之葡萄糖代謝,結果發現,lunasin處理能顯著增加C2C12細胞對葡萄糖之利用,但不影響到胰島素阻抗之表現。綜合上述,動物實驗中,HF-HL及HF-DL組可減緩肥胖小鼠葡萄糖耐受性異常推測可能經由調節血清與肝臟小分子代謝進而改善肥胖小鼠部分代謝異常情形。而飲食中添加富含lunasin的大豆蛋白對肥胖小鼠之影響不如腹腔注射lunasin純品效應強烈。而lunasin如何調控肥胖小鼠生理與對骨骼肌細胞葡萄糖代謝影響之相關路徑,值得進一步探討。

The worldwide prevalence of obesity has largely increase according to epidemiologic studies. Obesity is related to many diseases, such as metabolic syndrome, and causes physiological changes in blood sugar, blood lipids, blood pressure, metabolic disorders, and insulin resistance. Lunasin, a seed peptide, exerts many bioactive functions including cancer prevention, immune regulation, anti-oxidation and anti-cholesterol. The aim of this study is to investigate the effect of lunasin on serum biochemical analysis, and metabolic profiling of serum and liver in high-fat diet-induced obese C57BL/6J mice. Additionaly, C2C12 skeleton muscle cells were invesigated the effect of lunasin on glucose uptake and insulin sensitivity. In vivo, mice were divided to five groups and fed experimental diets, including low-fat diet (LF) or high-fat diet (HF), HF with intraperitoneal injected (IP) with 4 or 20 mg/kg bw/day synthetic lunasin (HF-LL, HF-HL), and supplemented lunasin of natural soy protein isolate in diet (20 mg/kg bw/day, HF-DL). The data has shown that high dose of lunasin IP and lunasin of natural soy protein isolate significantly improve glucose tolerance in obese mice. However, lunasin treatment didn’t affect serum levels of glucose, insulin, TG and cholesterol, and MDA formation in liver of mice. In the metabolic profiling, mice of HF group have shown that the metabolic intermediates of TCA cycle, glycolysis and uric acid were increased, and metabolites related to bile acid and amino acid were decrease compared to the LF group. Lunasin treatment modulated abnormally changes of those metabolites. In vitro, C2C12 cells were treated with synthetic lunasin and lunasin-enriched soy protein isolate. The data has showed that lunasin increased glucose uptake in C2C12 cells, but it doesn’t affect insulin resistance. In conclusion, our results demonstrated that high-dose IP of lunasin and lunasin dietary intake prevented glucose intolerance in obese mice. Lunasin treatment improving metabolic disorders in obese mice were found in metabolic profiling analysis. More research need to be carried out to know the mechanism of metabolic regulation in obese mice and the signaling pathway of glucose homeostasis in mice muscle cells.

摘要 i Abstract ii 目錄 iii 圖目錄 vi 表目錄 vii 第一章 文獻探討 1 第一節 肥胖 1 一 簡介 1 二 流行病學調查 1 三 肥胖與代謝症候群 2 四 肥胖的生理與代謝 3 第二節 Lunasin 5 一 簡介 5 二 Lunasin生理功能 6 第三節 研究工具 9 一 高脂飲食誘發C57BL/6J小鼠肥胖模式 9 二 C2C12小鼠骨骼肌細胞 10 三 代謝體分析 11 第二章 研究動機與目的 14 第一節 動機與目的 14 第二節 研究架構 15 第三章 材料與方法 16 第一節 實驗藥品來源 16 第二節 實驗細胞與實驗動物來源 16 一 實驗細胞來源 16 二 實驗動物來源 16 第三節 實驗設備與耗材 16 一 實驗儀器設備 16 二 拋棄式無菌耗材 17 三 細胞培養常用材料 17 第四節 實驗材料與方法 19 一 大豆分離蛋白之樣本選擇 19 (一) 預實驗:lunasin純化 19 (二) 預實驗:蛋白質及lunasin定量分析 20 (三) 檢測大豆異黃酮 21 (四) 大豆分離蛋白P974純化為LES之蛋白質及lunasin定量分析 21 二 Lunasin處理對餵食高脂飲食之C57BL/6J小鼠血清與肝臟代謝之影響 23 (一) Lunasin處理對肥胖小鼠之血液生化值及小分子代謝體之影響 23 (二) 動物飼料配製 24 (三) 動物犧牲、小鼠血液及組織器官樣本分析與測定 26 1 禁食葡萄糖耐受性試驗 26 2 小鼠犧牲,血液、器官與組織之取得 26 3 血清生化值分析 27 4 胰島素定量與胰島素抗性指標 30 5 脂質過氧化指標 (TBARS)之測定 31 6 組織切片與染色分析 32 7 血清與肝臟之小分子代謝體分析 32 三 Lunasin處理對C2C12小鼠骨骼肌細胞葡萄糖攝入與胰島素敏感性之影響 34 (一) C2C12小鼠肌肉纖維母細胞培養 34 (二) C2C12小鼠肌肉纖維母細胞分化 34 (三) C2C12小鼠骨骼肌細胞之葡萄糖攝入 34 (四) C2C12小鼠骨骼肌細胞之胰島素敏感性 36 四 統計分析 37 第四章 實驗結果 38 第一節 大豆分離蛋白之樣本選擇 38 一 大豆分離蛋白之lunasin純化及其蛋白質與lunasin定量分析 38 二 純化後大豆分離蛋白之大豆異黃酮檢測與分析 39 三 大豆分離蛋白P974之lunasin純化 40 四 LES之蛋白質與lunasin定量分析 40 第二節 Lunasin處理對餵食高脂飲食之C57BL/6J小鼠血清及肝臟代謝之影響 41 一 Lunasin處理對肥胖小鼠體重變化及攝食效率之影響 41 二 Lunasin處理對肥胖小鼠組織重量變化之影響 43 三 Lunasin處理對肥胖小鼠禁食葡萄糖耐受性之影響 44 四 Lunasin處理對肥胖小鼠血清生化值之影響 45 五 Lunasin處理對肥胖小鼠胰島素及胰島素抗性之影響 49 六 Lunasin處理對肥胖小鼠肝臟組織TBARS之影響 50 七 Lunasin處理對肥胖小鼠肝臟組織H&E染色之影響 51 八 Lunasin處理對肥胖小鼠血清與肝臟小分子代謝體之影響 52 第三節 Lunasin處理對小鼠C2C12骨骼肌細胞葡萄糖利用與胰島素阻抗之影響 61 一 Lunasin處理對小鼠C2C12骨骼肌細胞葡萄糖代謝之影響 61 二 Lunasin處理對小鼠C2C12骨骼肌細胞胰島素敏感性之影響 62 第五章 討論 63 第一節 大豆分離蛋白之樣本選擇與P974之純化及定量分析 63 第二節 Lunasin處理對餵食高脂飲食之C57BL/6J小鼠血清與肝臟代謝之影響 64 一 Lunasin處理對肥胖小鼠體重、攝食及組織重量之影響 64 二 Lunasin處理對肥胖小鼠葡萄糖耐受性、血清生化值及胰島素之影響 65 三 Lunasin處理對肥胖小鼠脂質過氧化物之影響 67 四 Lunasin處理對肥胖小鼠血清與肝臟小分子代謝體之影響 68 五 Lunasin處理對小鼠C2C12骨骼肌細胞葡萄糖代謝之影響 74 第六章 結論 76 第七章 參考文獻 77

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