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研究生: 彭詩涵
Peng, Shih-Han
論文名稱: Lunasin對肥胖因子影響MCF-7與MDA-MB-231人類乳癌細胞生長之探討
The effects of lunasin on the growth of obesity-mediated MCF-7 and MDA-MB-231 human breast cancer cells
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: 2018
畢業學年度: 106
語文別: 中文
論文頁數: 109
中文關鍵詞: Lunasin肥胖乳癌巨噬細胞
英文關鍵詞: Lunasin, Obesity, Breast Cancer, Macrophage
DOI URL: http://doi.org/10.6345/THE.NTNU.DHDFS.033.2018.A06
論文種類: 學術論文
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  • 流行病學研究顯示,過重或肥胖會增加女性罹患乳癌的風險,而肥胖過程中脂肪組織會有巨噬細胞浸潤情形,伴隨著促發炎性細胞激素的分泌而營造出一個慢性發炎的環境,適合腫瘤發展。此外,過多脂肪累積會增加aromatase的表現與活性,導致雌二醇生成增加,促使乳癌惡化。Lunasin為一種子胜肽,由43個胺基酸組成,目前研究證實具有抗腫瘤、抗發炎、抗氧化…等生理功能。然而Lunasin對肥胖相關人類乳癌細胞中的發炎介質、雌激素及芳香酶表現仍然未知。本實驗目的為探討Lunasin的介入是否會抑制肥胖微環境下雌激素依賴型MCF-7細胞及非依賴型MDA-MB-231乳癌細胞的生長並抑制其發炎反應及芳香酶表現。第一部分探討肥胖微環境是否影響乳癌發展。結果顯示在肥胖微環境下,以DMBA誘發癌化之NIH/3T3其foci數量會增加。在動物實驗發現,以DMBA誘發肥胖小鼠的乳癌腫瘤中,其腫瘤中細胞增殖能力(Ki67)與巨噬細胞浸潤(F4/80)的表現增加,副睪脂肪的M1型巨噬細胞(CD11c)及F4/80的表現也會上升,高脂飲食會降低M2型巨噬細胞(CD206)的表現,而Lunasin介入可抑制高脂飲食中的F4/80及CD11c的表現。第二部分為探討Lunasin對兩株雌激素依賴型相異的人類乳癌細胞之影響。結果顯示,MCF-7細胞在48小時之IC50為92.5 μM而MDA-MB-231細胞為136.3 μM。將細胞培養在3T3脂肪細胞條件培養液(Adipocyte conditioned medium, Ad-CM)環境下,Lunasin的處理皆能顯著抑制其兩株細胞的存活率。在細胞週期的部分,肥胖微環境下,Lunasin有將MCF-7細胞停滯在G2/M期的能力。細胞活性分析中,無論在有無Ad-CM的環境下, Lunasin的介入皆會抑制MCF-7的細胞活性,而MDA-MB-231僅在新鮮培養基下降低。另外,兩株細胞在新鮮培養基下經Lunasin處理後細胞凋亡皆增加,且芳香酶活性皆下降。
    綜上所述,Lunasin可降低肥胖小鼠巨噬細胞的發炎反應,抑制乳癌細胞生長,並可降低乳癌細胞活性,增加細胞凋亡,並抑制芳香酶活性。因此,推測出富含Lunasin的飲食型態可能有助於乳癌患者的輔助治療,尤其是雌激素依賴型的乳癌。

    The epidemiological studies have showed that the women with overweight or obesity have higher risk developed breast cancer. In adipogenesis, macrophages infiltrate into adipose tissue and accompany pro-inflammatory mediator secretions promoting cancer progression. In addition, excecive fat accumulation increase the expression and activity of aromatase, causing estradiol overproduction and promote the progression of breast cancer. Lunasin is a soy pepride which consist of 43 amino acids, the bioactivities of lunasin on chemopreventation, anti-inflammation and anti-oxidation have been widely studied. However, the effect of lunasin on obesity-related inflammation mediators secretion, estrogen production and aromatase expression in breast cancer cells are still uncertained. The aim of this work is to investigate whether lunasin can inhibit the growth of MCF-7 and MDA-MB-231 cells, and downregulate the inflammation in the microenvironment. First part is to find out the effect of obesity-related microenvironment on the progression of breast cancer. The results showed that that the number of DMBA-induced foci formation upregulated in obesity microenvironment in vitro studied. In vivo, F4/80, a macrophages infiltration marker, and cell proliferation increased in DMBA-induced mammary tumor in obese mice. Also, F4/80 and CD11c, a M1 macrophages marker, increased in Epididymal adipose tissue when DMBA intervention. Additionally, CD206, a M2 macrophages marker, decreased in obese mice. In addition, lunasin inhibit F4/80 and CD11c in obese mice. Second part is to investigate the effect of lunasin on estrogen dependent and estrogen independent breast cancer cells. The result revealed that after treatment with lunasin for 48h, the IC50 values in MCF-7 cells is 92.50 μM and in MDA-MB-231 cell is 136.3 μM. When incubate in 3T3-L1 adipocyte conditioned medium(Ad-CM), lunasin can inhibit cell viability in both MCF-7 and MDA-MB-231, and cell cycle arrested at G2/M phase in MCF-7. In cell vitality assay, no matter incubation with Ad-CM or not, lunasin intervention increase low vitality cells in MCF-7, but this result only found in MDA-MB-231 when incubation with fresh medium. At last, lunasin intervention increase apoptosis and decrease aromatase activity in both of breast cancer cells. In summary, lunasin downregulate inflammation in obese mice, inhibit the growth, vitality and aromatase activity and upregulate the apoptosis of breast cancer cells, which indicate that lunasin-enrich dietary life syle might be a promising adjuvant therapy to obesity-related cancer, especially estrogent dependent breast cancer.

    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、肥胖與免疫 1 四、肥胖與癌症 4 第二節、乳癌 5 一、簡介 5 二、乳癌與肥胖 6 (一) 脂肪激素 6 (二) 細胞激素與受器 7 (三) 脂肪細胞對aromatase表現與雌激素生成的影響 12 (四) 肥胖對雌激素受器的影響 13 三、乳癌與植化素 14 第三節、Lunasin 17 一、簡介 17 二、消化吸收 17 三、Lunasin生理功能 19 (一) 抗腫瘤 19 (二) 抗發炎與抗氧化 21 (三) 其他功效 22 第四節、研究工具 24 (一) DMBA誘發乳腺腫瘤模式 24 (二) 3T3-L1小鼠纖維母細胞 24 (三) 乳癌細胞 24 (四) 3T3-L1與人類乳癌細胞共培養 24 第二章、研究動機與目的 26 第一節、動機與假說 26 第二節、研究架構 28 第三章、實驗材料與方法 29 第一節、實驗材料 29 一、藥品來源 29 二、細胞來源 29 三、實驗儀器設備 29 四、拋棄式無菌耗材 30 五、細胞培養常用材料 30 第二節、實驗方法 31 一、細胞培養 31 二、建立體外肥胖發炎模式 32 (一) 3T3-L1小鼠纖維母細胞分化 32 三、肥胖發炎微環境對以化學致癌劑誘發癌化的細胞之影響 33 (一) 肥胖發炎因子對給予DMBA誘發癌化的NIH/3T3的foci生成影響 33 四、Lunasin處理對RAW 264.7巨噬細胞其表型的影響 34 (一)RAW 264.7細胞標記之分析 34 五、肥胖微環境對於人類乳癌細胞生長影響 35 (一) Ad-CM對細胞存活率的影響 35 六、Lunasin的處理對肥胖微環境下人類乳癌細胞之生長影響 35 (一)細胞存活率測定 35 (二)細胞週期與細胞活性 36 (三)細胞凋亡 37 (四)芳香酶活性測定 38 (五)細胞激素分析:酵素連結免疫吸附分析(ELISA) 39 (六)基因表現量分析 42 六、動物實驗 44 (一)DMBA誘發肥胖小鼠乳癌生成 44 (二) Lunasin腹腔注射對高油飲食誘發肥胖小鼠的影響 44 七、組織切片染色 44 第三節、統計分析 46 第四章、實驗結果 47 第一節、肥胖因子對乳癌發展的影響 47 一、肥胖因子對於DMBA誘發NIH/3T3細胞 foci生成的影響 47 二、DMBA誘發肥胖小鼠乳癌生成之腫瘤組織切片其型態表現 49 三、DMBA誘發肥胖小鼠乳癌生成其副睪脂組織切片之巨噬細胞表現型 50 四、Lunasin處理對RAW 264.7小鼠巨噬細胞表現型之影響 53 五、Lunasin處理對肥胖小鼠其副睪脂組織切片巨噬細胞表現型之影響 55 第二節、在肥胖微環境下Lunasin處理對人類乳癌細胞MCF-7及MDA-MB-231的生長影響 58 一、Lunasin處理對人類乳癌細胞存活率的影響 58 二、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞存活率的影響 60 三、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞週期的影響 63 四、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞活性的影響 65 五、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞凋亡的影響 70 六、Lunasin處理對肥胖微環境下人類乳癌細胞其芳香酶活性的影響 73 七、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞激素的影響 74 八、Lunasin處理對肥胖微環境下人類乳癌細胞其基因表現的影響 77 第五章、討論 78 第一節、肥胖因子對乳癌發展的影響 78 一、肥胖因子對於以DMBA誘發癌化的影響 78 二、DMBA誘發肥胖小鼠乳癌生成之腫瘤組織切片之型態表現 79 三、Lunasin處理對肥胖微環境下巨噬細胞表現型之影響 80 第二節、Lunasin處理對肥胖微環境之人類乳癌細胞MCF-7及MDA-MB-231的生長影響 81 一、Lunasin與肥胖微環境對人類乳癌細胞存活率的影響 81 二、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞週期的影響 82 三、Lunasin處理對肥胖微環境下人類乳癌細胞其細胞活性及細胞凋亡的影響 83 四、Lunasin處理對肥胖微環境下人類乳癌細胞其芳香酶活性及細胞激素的影響 84 第六章、結論 88 第七章、附錄 90 第八章、參考文獻 91

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