目錄

壹、研究背景與目的 1
一、研究背景 1
二、研究目的 2

貳、文獻整理 3
一、稀有醣類 3
1. 簡介 3
2. 酵素轉換法生成稀有糖例子 3
3. L-核酮糖 (L -ribulose) 3
4. L-核糖 (L-ribose) 3
二、L-核糖 (L-ribose)之生產 4
1. 生產方式 4
2. 生產L-核糖需要的酵素 4
三、重組蛋白在ClearColiTM BL21 (DE3)中之蛋白質表現 5
1. ClearColiTM BL21 (DE3) 5
2. pET 表現系統 6
3. 乳糖操控組 (lactose operon) 6
四、化學伴護子 (chemical chaperone) 6
五、發酵技術 7
1. 發酵簡介 7
2. 發酵槽種類 7
3. 發酵槽培養方式 7
六、固定化 8
1. 固定化方式 8
2. 吸附法材料介紹 9

參、實驗設計與流程 11
以小量培養探討突變型Af-RI 及Ts-AI 的最適培養條件 11
二、以發酵槽進行培養探討饋料方式對於Af-RI 及Ts-AI 菌體收穫量與酵
素活性的影響 11
三、固定化酵素之方法與特性探討 11
四、L-核糖及 L-核酮糖之生產 12

肆、實驗材料與方法 13
一、 材料 13
1. 菌株與載體 13
2. 抗生素 13
3. 標準品 13
4. 市售套組 13
5. 培養基 13
6. 化學藥品 13
7. 實驗設備 15
二、 藥品配置 17
三、 實驗步驟及方法 19
1. 電穿孔轉形作用 19
1.1 宿主 19
1.2 製備 E. coli 電穿孔勝任細胞 19
1.3 電轉形作用 (electrotransformation) 20
1.4 菌種保存 20
2. 小量重組型Af-RI 及 Ts-AI 之表現 20
2.1 以不同條件誘導表現重組型Af-RI 及 Ts-AI 20
2.2 SDS-PAGE 21
3. 發酵槽培養 23
3.1 批式培養 23
3.2 批式饋料培養-定速追加饋料 23
3.3 批式饋料培養-pH-stat 24
4. 重組型 F270N Ts-AI 及 F141Y Af-RI 純化 24
5. 蛋白質定量 25
6. 活性分析與特性探討 25
6.1 酵素活性分析 25
6.2 重組型 F270N Ts-AI 酵素活性測定 25
6.3 重組型 F141Y Af-RI 酵素活性測定 25
6.4 固定化酵素測定 26
7. 活性碳-固定化酵素的製備與特性探討 26
7.1 活性碳-固定化酵素之微觀結構 26
7.2 活性碳-固定化酵素之最適結合溫度 26
7.3 活性碳-固定化酵素之最適作用pH 27
7.4 活性碳-固定化酵素之重複使用性 27
8. 離子交換樹脂-固定化酵素分析與特性探討 27
8.1 Q Sepharose-固定化酵素(Q Sepharose-immobilized enzyme) 27
8.2 Amberlite-固定化酵素 27
8.3 Q Sepharose-固定化酵素之最適溫度 27
8.4 Q Sepharose-固定化酵素之最適pH 27
8.5 Q Sepharose-固定化酵素之半衰期 28
8.6 Q Sepharose-固定化酵素之儲藏性 28
9. 以固定化酵素及純化酵素進行L-核糖的生產 28

伍、結果與討論 30
一、 F141Y Af-RI 表現及純化 30
1. 利用小量培養進行條件探討 30
2. 以發酵槽進行大量生產 30
二、 F270N Ts-AI 表現及純化 31
1. 利用小量培養進行條件探討 31
2. 以發酵槽進行大量生產 31
三、 固定化 32
1. 活性碳 32
2. 離子交換樹脂 33
四、 生產 L-核糖與 L-核酮糖 35

陸、結論 36

柒、參考文獻 37

捌、圖表 46

玖、附錄 86

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