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研究生: 黃堃愷
Huang, Kun-Kai
論文名稱: 三核苷酸重複序列對 SSB 的載入和再分佈之影響
Influence of Trinucleotide Repeat Sequences to the SSB Loading and Redistribution
指導教授: 李以仁
Lee, I-Ren
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2019
畢業學年度: 107
語文別: 中文
論文頁數: 67
中文關鍵詞: 單分子螢光共振能量轉移單股 DNA 結合蛋白CTG 重複序列三核苷酸重複序列
英文關鍵詞: single-molecule fluorescence resonance energy transfer (smFRET), Single-stranded DNA binding protein (SSB), Trinucleotide repeat (TNR) expansions, CTG repeat sequence
DOI URL: http://doi.org/10.6345/NTNU201900450
論文種類: 學術論文
相關次數: 點閱:144下載:0
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  • 三核苷酸重複序列 (Trinucleotide repeat, TNR) 的擴張是導致許多神經退化性疾病的原因,而三核苷酸重複序列通常會折疊成二級結構,如:髮夾型結構,因此會在 DNA 進行複製、重組和修復的過程時中斷蛋白質的運作機制,並且這也被認為是造成錯誤擴增序列的主要原因。
    單股 DNA 結合蛋白 (Single-stranded DNA binding protein, SSB) 是能夠在上述過程中結合單股 DNA 的主要蛋白,同時可以解開二級結構的能力,在這裡,我們使用大腸桿菌 SSB (Escherichia coli SSB, EcoSSB) 和 CTG 重複序列作為模型系統,並利用單分子螢光共振能量轉移光譜學 (single-molecule fluorescence resonance energy transfer, smFRET) 來研究三核苷酸重複序列對單股 DNA 結合蛋白的載入和重新分佈之影響。我們發現,相對於隨機捲曲的單股 DNA,三核苷酸重複序列的髮夾型結構嚴重阻礙單股 DNA 結合蛋白的負載;另一方面,當單股 DNA 結合蛋白負載到含有 CTG 重複序列和短單股 DNA的末端時,其過程中大約歷經數十分鐘的中間態而最後達到反應平衡,最後平衡的結構仍具有高度動態的結構變化,這表明單股 DNA 結合蛋白可以部分解開 CTG 重複序列的髮夾型結構,並在其當中進行擴散以重新分佈。

    Trinucleotide repeat (TNR) expansions are responsible for many neurodegenerative disorders. TNRs usually fold into secondary structures such as hairpins, which interrupt protein machinery during DNA replication, recombination, and repair processes, and are believed to be the primary cause for the error-prone expansion. Single-stranded DNA binding protein (SSB), an essential protein that binds single-stranded DNA (ssDNA) during the abovementioned processes, has been shown the capability of unwinding secondary structures.
    Here, we use Escherichia coli SSB (EcoSSB) and CTG repeat sequences as a model system to investigate the influence of TNR hairpin structure for the SSB loading and redistribution, utilizing single-molecule fluorescence resonance energy transfer (smFRET) spectroscopy. We found that TNR hairpins severely impede the loading of SSB compared to random-coiled ssDNA. On the other hand, when EcoSSB is preloaded onto the assay containing CTG hairpin and a short ssDNA loading end, it reaches the equilibrated configuration through an intermediate state in the order of tens minutes. The equilibrated configuration is highly dynamic, suggesting EcoSSB can partially unwind CTG hairpin and diffuse along it.

    謝誌 i 摘要 ii Abstract iii 目錄 iv 圖目錄 vi 表目錄 ix 第一章、緒論 1 1-1前言 1 1-2致病原因 3 1-3 重複序列造成之非典型 DNA 二級結構 4 1-4 DNA重複序列的擴張機制 6 1-5 三核苷酸重複序列 (CTG)n 的滑動現象 8 1-6 單股 DNA 結合蛋白 9 1-7 研究動機 12 第二章、實驗方法與儀器 13 2-1 實驗技術 13 2-1-1 單分子實驗技術 13 2-1-2 螢光共振能量轉移 15 2-1-3 全內反射式螢光顯微鏡 17 2-2 實驗樣品槽之製備組裝 19 2-2-1 實驗樣品槽的製備 19 2-2-2 實驗樣品槽的組裝 22 2-2-3 設計實驗序列 23 2-2-4 實驗序列的螢光分子標記 24 2-2-5 實驗序列的副序列黏合反應 25 2-2-6 實驗序列之分子內二聚體去除反應 26 2-2-7 實驗序列固定於樣品槽 27 2-2-8 影像緩衝溶液 (Imaging Buffer) 28 2-3 實驗數據處理與分析 31 2-3-1 實驗數據處理 31 2-3-2 數據擬合分析 34 第三章、實驗結果與討論 36 3-1 實驗設計 36 3-2 EcoSSB 蛋白與 dT65 之結合模式鑑定 37 3-3 EcoSSB 蛋白與三核苷酸重複序列 (CTG)n 之結合 38 3-4 在稍低鈉離子濃度下 EcoSSB 蛋白對三核苷酸重複序列 (CTG)n髮夾結構之影響 40 3-5 EcoSSB 蛋白與具有可供預載之突出的 (CTG)n 髮夾結構作用 41 3-5-1 高濃度的 EcoSSB 蛋白 (10 nM SSB) 41 3-5-2 低濃度的 EcoSSB 蛋白 (1 nM SSB ) 42 3-6 單分子 EFRET 變化分析 45 3-7 轉換密度圖 (TDP) 分析 46 第四章、結論 58 第五章、未來展望 60 參考文獻 61 附錄 66

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