具不同蔗糖合成酶 RSuS3 表現量之轉殖水稻建立及性狀分析

Te-Ching Chang; 張德清

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/24154

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王愛玉(Ai-Yu Wang)
dc.contributor.author	Te-Ching Chang	en
dc.contributor.author	張德清	zh_TW
dc.date.accessioned	2021-06-08T05:17:11Z	-
dc.date.copyright	2006-02-16
dc.date.issued	2005
dc.date.submitted	2006-01-06
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Wacher, R., Langhans, M., Aloni, R., Gotz, S., Weilmunster, A., Koops, A., Temguia, L., Mistrik, I., Pavlovkin, J., and Rascer, U. (2003). Vascularization, high-volumn solution flow, and localized roles for enzymes of sucrose metabolism during tumorigenensis by Agrobcterium tumefaciens. Plant Physiol 133, 1024-1037. Wang, A.Y., Yu, W.P., Juang, R.H., Huang, J.W., Sung, H.Y., and Su, J.C. (1992). Presence of three rice sucrose synthase genes as revealed by cloning and sequencing of cDNA. Plant Mol Biol 18, 1191-1194. Wang, F., Smith, A.G., and Brenner, M.L. (1994). Temporal and spatial expression pattern of sucrose synthase during tomato fruit development. Plant Physiol 104, 535-540. Wang, A.Y., Kao, M.H., Yang, W.H., Sayion, Y., Liu, L.F., Lee, P.D., and Su, J.C. (1999). Differentially and developmentally regulated expression of three rice sucrose synthase genes. Plant Cell Physiol 40, 800-807. Winter, H., Huber, J.L., and Huber, S.C. (1997). Membrane association of sucrose synthase: changes during the graviresponse and possible control by protein phosphorylation. FEBS Lett 420, 151-155. Winter, H., Huber, J.L., and Huber, S.C. (1998). Identification of sucrose synthase as an actin-binding protein. FEBS Lett 430, 205-208. Wolosiuk, R.W., and Pontis, H.G. (1971). Evidence of the existence of two forms of sucrose synthetase. FEBS Lett 16, 237-240. Yen, S.F., Su, J.C., and Sung, H.Y. (1994). Purification and characterization of rice sucrose synthase isozymes. Biochem Mol Biol Int 34, 613-620. 莊榮輝 (1985) 水稻蔗糖合成酶之研究－其純化、生物化學及免疫性質之比較。博士論文，國立台灣大學農業化學研究所。王愛玉 (1989) 水稻蔗糖合成酶之分子生物學研究。博士論文，國立台灣大學農業化學研究所。余維平 (1989) 水稻蔗糖合成酶基因結構之研究。博士論文，國立台灣大學農業化學研究所。岩素芬 (1992) 水稻蔗糖合成異構酶之純化與鑑定。博士論文，國立台灣大學農業化學研究所。陳任道 (1995) 水稻蔗糖合成酶異構基因之研究。博士論文，國立台灣大學農業化學研究所。廖憶純 (2002) 水稻懸浮培養細胞中蔗糖合成酶基因表現受糖調控之研究。博士論文，國立台灣大學農業化學研究所。蔡承佳 (2003) 蛋白質磷酸化對水稻蔗糖合成酶酵素功能及基因表現的影響。博士論文，國立台灣大學農業化學研究所。黃德宜 (2003) 水稻蔗糖合成酶 RSuS3 基因表現與酵素功能之探討。博士論文，國立台灣大學農業化學研究所。洪傳揚 (2003) 利用轉殖水稻種子表現重組蛋白質之研究。博士論文，國立台灣大學農藝學系。張睿哲 (2004) 水稻蔗糖合成酶 RSus1 基因調控區域中 cis-elements 之研究。國立台灣大學微生物與生化學研究所。郭益全、范明仁 (1999) 稻種原演化與環境適應性。環境與稻作生產。臺灣省農業試驗所。33-51。
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/24154	-
dc.description.abstract	蔗糖合成酶催化蔗糖與 UDP形成果糖與 UDP-glucose 的可逆反應。在水稻中，此酵素是由至少六種 RSus 基因所表現，其中 RSus3 主要表現於發育中的種子。本論文的目的在建構具有不同 RSus3表現量的轉殖水稻，以探討 RSus3 的生理功能。將預期可造成水稻各組織中恆常性表現 RSus3、於穀實中過量表現 RSus3 及於穀實中抑制 RSus3 表現的三種質體 pActinSuS3、pGluB1SuS3 及 pSuS3RNAi，經由農桿菌法轉殖到水稻。pActinSuS3 及 pGluB1SuS3 的 T0 及 T1 轉殖株，以 Southern 分析後發現，這些轉殖株帶有一個或二個外來的 RSus3 基因，且能夠在葉子偵測到其表現。分析 T1 植株充實期種子發現，轉殖株 RSus3 的表現比未轉殖之台農 67 號水稻早，轉殖株 RSus3 mRNA 的量也比未轉殖之台農 67 號水稻多。此外，轉殖株 T2 種子的千粒重及平均內外穎長有大於未轉殖之台農 67 號水稻的趨勢。	zh_TW
dc.description.abstract	Sucrose synthase catalyzes the reversible conversion of sucrose and UDP into fructose and UDP-glucose. The enzyme is encoded by at least six RSus genes in rice. One of the genes, RSus3, is predominatly expressed in the developing seeds. The objective of this study is to construct transgenic rice plants having different expression levels of RSuS3 in order to investigate the biological function of RSus3. Plasmids pActinSuS3, pGluB1SuS3 and pSuS3RNAi, which are expected to respectively result in constitutive expression of RSus3 in various rice tissues, over-expression of RSus3 in rice seed, and inhibition of RSus3 expression in rice seed were transformed into rice by the Agrobacterium-mediated method. Southern analysis of the T0 and T1 transgenic plants transformed with pActinSuS3 or pGluB1SuS3 revealed that one or two copies of RSus3 genes were introduced into these transgenic plants. Expression of RSus3 was detected in leaves. Analysis of ripening seeds of the T1 transgenic plants revealed that the expression of RSus3 in the developing seeds of these transgenic plants occurred earlier than the untransformed TNG67 rice plant. The abundance of RSus3 mRNA in the seeds of transgenic plants was also higher than the untransformed plant. Moreover, the weight of 1000 grains and the average length of grains of transgenic T2 seeds are larger than the untransformed TNG67.	en
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dc.description.tableofcontents	目錄..………………………………………………………………I 縮寫表………………………………………………………………VI 摘要…………………………………………………………………VII Abstract…………………………………………………………VIII 第一章緒論………………………………………………………1 第一節水稻………………………………………………………1 1.1 水稻簡介 1 1.2 水稻生長 1 第二節蔗糖合成酶………………………………………………2 2.1 蔗糖合成酶之生化特性 2 2.1.1 蔗糖合成酶催化之反應 2 2.1.2 蔗糖合成酶之一般生化特性 3 2.1.3 蔗糖合成酶異構酶與其基因 3 2.2 蔗糖合成酶的生理功能 4 2.2.1 參與澱粉之生合成 4 2.2.2 參與細胞壁多醣類之合成 4 2.2.3 參與蔗糖運輸 5 2.2.4 參與缺氧逆境反應 5 第三節水稻蔗糖合成酶之研究…………………………………5 第四節本篇論文之目的及方向…………………………………7 4.1 水稻植株中恆常性表現 RSuS3 7 4.2 水稻轉殖株穀實中過量表現 RSuS3 7 4.3 水稻轉殖株穀實中抑制 RSuS3 表現 8 第二章材料與方法………………………………………………9 第一節實驗材料與樣品…………………………………………9 1.1 轉殖作物 9 1.2 菌種 9 1.3 質體 9 1.4 藥品 10 第二節實驗儀器設備……………………………………………11 2.1 水平核酸電泳 11 2.2 蛋白質電泳轉印設備 11 2.3 離心機 11 2.4 其他 11 第三節實驗流程與方法…………………………………………12 3.1 實驗流程 12 3.2 重組質體構築 12 3.2.1 質體 DNA 之抽取 12 3.2.2 DNA 之定量法 13 3.2.3 DNA 限制酶切割 13 3.2.4 Klenow Fragment DNA 片段 5’ 端補齊 13 3.2.5聚合酶連鎖反應 13 3.2.6 DNA 片段純化 14 3.2.7 膠體中 DNA 片段之回收 14 3.2.8 接合反應 14 3.2.9 Competent cells 之製備 14 3.2.9.1 氯化鈣法 14 3.2.9.2 電轉形法 15 3.2.10 質體之轉形 15 3.2.10.1 氯化鈣法 15 3.2.10.2 電轉形法 15 3.2.11質體快速篩選法 16 3.2.12 DNA 瓊脂糖膠體電泳法 16 3.3 水稻農桿菌基因轉殖 16 3.3.1水稻癒合組織誘導 16 3.3.2農桿菌 competent cells 製備 17 3.3.3農桿菌之電轉形 17 3.3.4農桿菌轉殖水稻癒合組織 17 3.3.4.1農桿菌大量培養 17 3.3.4.2 農桿菌水稻癒合組織共培養 18 3.3.4.3 清洗癒合組織 18 3.3.4.4 第一次篩選 18 3.3.4.5 第二次篩選 18 3.3.4.6 分化與移植 18 3.3.5 水稻種子發芽 18 3.3.6 水稻農藝性狀調查及種子保存 19 3.4 Southern 分析 19 3.4.1 水稻染色體 DNA 之抽取 19 3.4.2 水稻染色體 DNA 限制酶作用 19 3.4.3 水稻染色體 DNA 瓊脂糖膠體電泳分析 20 3.4.4 轉印 20 3.4.5 放射線標定探針製備 20 3.4.6 雜合反應 20 3.5 RNA 之抽取與分析 21 3.5.1 水稻 total RNA 之抽取 21 3.5.2 水稻 total RNA 去 DNA 21 3.5.3 RNA 之定量法 22 3.5.4 反轉錄反應 (Reverse transcription) 22 3.6 Western 分析 22 3.6.1 水稻種子蛋白質抽取 22 3.6.2 蛋白質粗抽液定量 22 3.6.3 蛋白質 SDS-PAGE 電泳 22 3.6.4 蛋白質轉印 23 3.6.5 免疫呈色法 23 第三章結果與討論……………………………………………25 第一節質體建構…………………………………………………25 1.1 恆常性表現質體 pActinSuS3 之構築 25 1.2 穀實中過量表現質體 pGluB1SuS3 之構築 25 1.3 穀實中抑制 RSus3 表現之質體 pSuS3RNAi 之構築 25 第二節以農桿菌法進行台農 67 號水稻轉殖…………………26 2.1 農桿菌法轉殖過程 26 2.2 轉殖效率 27 2.3 轉殖株命名 27 2.4 轉殖株繁殖 27 第三節轉殖基因之分子檢定……………………………………28 3.1 T0 轉殖株 PCR 檢定 28 3.1.1 hpt II 基因之檢定 28 3.1.2 RSus3 基因之檢定 29 3.2 T0 轉殖株 Southern 分析 29 3.2.1 hpt II 基因之檢定 29 3.2.2 RSus3 基因之檢定 30 3.3 T1 轉殖株 Southern 分析 30 第四節轉殖基因之表現……………………………………………31 4.1 T0 轉殖株成熟葉 RT-PCR 分析 31 4.2 T1 轉殖株成熟葉 RT-PCR 分析 32 4.3 Glutelin 是否在成熟葉中表現 32 4.4 T1 轉殖株充實期種子分析 32 4.4.1 T1 轉殖株充實期種子 RT-PCR 分析 33 4.4.2 T1 轉殖株充實期種子 western 分析 33 第五節 T1 轉殖株表現型觀察及農藝性狀分析…………………33 第四章總結……………………………………………………35 第五章未來展望………………………………………………36 5.1 pSuS3RNAi 轉殖株之分析 36 5.2 轉殖株後代分析 36 5.3 轉殖株種子中澱粉及醣類分析 36 5.4 製備能夠區別水稻內生及外來 RSuS3 之抗體 36 參考文獻……………………………………………………………37 圖與表………………………………………………………………42 附錄…………………………………………………………………67
dc.language.iso	zh-TW
dc.subject	農桿菌基因轉殖	zh_TW
dc.subject	水稻蔗糖合成&#37238	zh_TW
dc.subject	rice sucrose synthase	en
dc.subject	agrobacterium mediated gene transformation	en
dc.title	具不同蔗糖合成酶 RSuS3 表現量之轉殖水稻建立及性狀分析	zh_TW
dc.title	Production and Characterization of Transgenic Rice Plants Expressing Various Abundance of Rice Sucrose Synthase Isoenzyme RSuS3	en
dc.type	Thesis
dc.date.schoolyear	94-1
dc.description.degree	碩士
dc.contributor.coadvisor	劉麗飛(Li-Fei Liu)
dc.contributor.oralexamcommittee	宋賢一(Hsien-Yi Sung),葉開溫(Kai-Wun Yeh),洪傳揚(Chwan-Yang Hong)
dc.subject.keyword	水稻蔗糖合成&#37238,農桿菌基因轉殖,	zh_TW
dc.subject.keyword	rice sucrose synthase,agrobacterium mediated gene transformation,	en
dc.relation.page	69
dc.rights.note	未授權
dc.date.accepted	2006-01-09
dc.contributor.author-college	生命科學院	zh_TW
dc.contributor.author-dept	微生物與生化學研究所	zh_TW
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