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研究生: 謝宇鈞
Hsieh, Yu-Chun
論文名稱: CRISPR/Cas9藉由基因體和表觀基因組的編輯精準地調節癌症幹細胞相關基因表達
CRISPR/Cas9-mediated genome and epigenome editing for precision modulation of cancer stem cell-related gene expression
指導教授: 李佳霖
Lee, Jia-Lin
口試委員: 張壯榮
CHANG, CHUANG-RUNG
王翊青
WANG, I-CHING
學位類別: 碩士
Master
系所名稱: 生命科學暨醫學院 - 分子與細胞生物研究所
Institute of Molecular and Cellular Biology
論文出版年: 2018
畢業學年度: 106
語文別: 中文
論文頁數: 57
中文關鍵詞: 癌症幹細胞肺癌基因敲除基因活化
外文關鍵詞: ELAVL1, HuR, dCas9, CancerStemCell, Knockout, VPR, SunTag, p300, VP64
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    • Clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated(Cas)protein 9(CRISPR/Cas9)的系統為基因敲除、敲入、活化、抑制和標記提供了精確的工具。在本次研究中,我們成功地使用CRISPR/Cas9敲除LM和HM20肺癌細胞中的癌症幹細胞相關基因ELAVL1(LM-ELAVL1-KO and HM20-ELAVL1-KO)。此外,為了進行有針對性的表觀遺傳修飾,我們使用dCas9 — 將Cas9核酸內切酶結構域突變,以產生核酸內切酶的功能喪失。dCas9與改變轉錄的蛋白質結構域融合,例如轉錄激活因子和組蛋白修飾因子。我們做出多個CRISPR-activated-ELAVL1的HM20克隆,像是HM20-dCas9VP64、HM20-dCas9VPR、HM20-dCas9p300 和HM20-dCas9SunTag。HuR(ELAVL1)是一種RNA的結合蛋白,和mRNA的穩定性和轉譯效率有關,也是調節細胞增生,生長和存活途徑的必要組成。我們發現ELAVL1敲除細胞(LM-ELAVL1-KO和HM20-ELAVL1-KO)的細胞遷移能力和增殖率顯著降低,而CRISPR / Cas9介導的表觀基因組編輯在ELAVL1激活細胞中這些功能有增加。有趣的是,細胞週期相關蛋白(如細胞週期蛋白B1)的表達在ELAVL1敲除細胞中減少,相反,這些基因在ELAVL1激活細胞中增加。我們可以通過CRISPR/Cas9介導的基因組和表觀基因組編輯來研究癌症幹細胞相關基因的功能。我們的結果可能為CRISPR/Cas9靶向癌症幹細胞相關基因的應用提供證據,作為一種新的治療策略,用於人類癌症治療。

    Clustered regularly interspaced short palindromic repeats(CRISPR)/CRISPR-associated(Cas)protein 9 system provides a precision tool for gene knockin, knockout, activation, suppression and labeling. In this study, we successfully used CRISPR/Cas9 to knockout a cancer stem cell- related genes, ELAVL1, in LM and HM20 lung cancer cells(LM-ELAVL1-KO and HM20-ELAVL1- KO). In addition, to make targeted epigenetic remodeling, researchers have mutated the nuclease domains of Cas9 to create a nuclease deficient(dCas9). dCas9 is fused to a protein domain that alters transcription, such as a transcriptional activator and histone modifier. We generated several CRISPR-activated-ELAVL1 HM20 clones, including HM20-dCas9VP64, HM20-dCas9VPR, HM20-dCas9p300 and HM20-dCas9SunTag. HuR(ELAVL1)is a RNA-binding protein which modulates the stability and translational efficiency of mRNA encoding essential components of cellular proliferation, growth and survival pathways. We found that the cell migration ability and proliferation rate were significantly reduced in ELAVL1-knockout cells(LM-ELAVL1-KO and HM20-ELAVL1-KO), whereas those functions were increased in ELAVL1-activation cells by CRISPR/Cas9-mediated epigenome editing. Interestingly, the expression of cell cycle-related proteins, such as cyclin B1, were reduced in ELAVL1-knockout cells, on the contrary, those genes were increased in ELAVL1-activation cells. We can investigate the functions of cancer stem cell- related genes by CRISPR/Cas9-mediated genome and epigenome editing. Our results may provide evidence for application of CRISPR/Cas9 targeting cancer stem cell-related genes, as a new treatment strategy, in human cancer therapy.

    Abstract 1 摘要 2 Abbreviation Index 3 Content 4 Figure legends 7 Chapter 1. Introduction 8 1.1 淺談CRISPR / Cas 8 1.2 CRISPR / Cas9 的組成與其功能 8 1.3 CRISPR / Cas9 的應用 9 1.4 Cas9 vs. dCas9 9 1.5 CRISPRa — CRISPR activation 10 1.6 ELAVL1 gene / HuR protein 的功能與介紹 10 1.7 HuR和癌症的關係 10 1.8 CD133 - Cancer Stem Cell Marker 11 1.9 EMT : Epithelial to Mesenchymal Transition 11 1.10 預期目標 11 Chapter 2. Material and Method 12 2.1 細胞培養與繼代(Cell culture and passage) 12 2.2 細胞冷凍與解凍(Cell cryopreservation and thawing) 12 2.2.1 細胞冷凍 12 2.2.2 細胞解凍 12 2.3 質體萃取(Plasmid extraction) 12 2.4 細胞轉染(Cell transfecting) 13 2.5 CRISPR/Cas9的細胞株挑選 13 2.5.1 質體轉染(Plasmid Transfection) 13 2.5.2 抗生素篩選(Antibiotic selection) 14 2.5.3 序列稀釋(Limiting dilution) 14 2.6 西方墨點法(Western Blot ) 14 2.6.1 Total cell lysis 14 2.6.2 SDS-PAGE電泳 15 2.6.3 轉膜(Transfer ) 15 2.6.4 免疫雜交法 15 2.6.5 抗體比例 15 2.7 細胞免疫螢光染色(Immunocytochemistry) 16 2.8 T7E1 assay 16 2.8.1 Genomic DNA 抽取 16 2.8.2 PCR 純化 17 2.8.3 Heteroduplexes形成 17 2.8.4 Heteroduplexes切割 18 2.9 RT-PCR(Reverse Transcription-PCR) 18 2.9.1 抽取Total RNA 18 2.9.2 酒精沈澱 18 2.9.3 反轉錄(Reverse Transcription) 19 2.10 細胞生長檢測(Cell proliferation assays) 19 2.11 數據的量化與統計分析 19 2.12 溶液成份表 20 Chapter 3. Results 22 3.1 尋找最適合的sgRNA 22 3.2 測試Puromycin的濃度 22 3.3 製備CRISPR/Cas9細胞株的優化步驟 22 3.4 選用四種不同的CRISPRa系統作為比較 23 3.5 CRISPR/Cas9所介導的基因剔除 23 3.5.1 細胞株選擇 23 3.5.2 T7E1的檢測 24 3.5.3 細胞免疫螢光染色和西方墨點法的檢測 24 3.6 ELAVL1 gene的表現與細胞增生的關係 24 3.7 dCas9-Activator對於增強ELAVL1 gene的能力 24 3.7.1 dCas9-VP64對於增強ELAVL1 gene的能力 24 3.7.2 dCas9-VPR對於增強ELAVL1 gene的能力 25 3.7.3 dCas9-p300對於增強ELAVL1 gene的能力 25 3.7.4 dCas9-SunTag對於增強ELAVL1 gene的能力 25 3.8 不同ELAVL1的表現量對於Cyclin B1的關係 25 3.9 不同ELAVL1的表現量對於CD133的關係 26 3.10 不同ELAVL1的表現量對於N-Cadherin的關係 26 Chapter 4. Discussion 27 4.1 挑選CRISPR/Cas9介導剔除ELAVL1 gene的細胞株 27 4.2 四種不同dCas9-Activator提升ELAVL1 gene的能力 27 4.3 剔除ELAVL1影響細胞生長 28 4.4 下調ELAVL1表現量增加Cancer Stem Cell Marker 28 4.5 降低ELAVL1表現量促進EMT的發生 28 Chapter 5. Conclusion and Implications 29 References 30

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