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研究生: 呂冠儒
Kuan-Ju Lu
論文名稱: FLOWERING LOCUS T (FT)訊息核醣核酸可在韌皮部移動並且有類開花素之特性
The mRNA of FLOWERING LOCUS T (FT) is a phloem mobile RNA and may act as a florigen-like molecule
指導教授: 陸重安
Chung-An Lu
余天心
Tien-Shin Yu
口試委員:
學位類別: 碩士
Master
系所名稱: 生醫理工學院 - 生命科學系
Department of Life Science
畢業學年度: 95
語文別: 英文
論文頁數: 50
中文關鍵詞: 訊息核醣核酸韌皮部開花素
外文關鍵詞: FLOWERING LOCUS T, phloem, florigen
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    • 在高等植物的生長發育過程中,決定由營養時期轉變為繁殖時期是一個非常重要的步驟。為了能夠讓後代在最適合的環境下生長,植物必須根據周圍環境的變遷來調節它們的由營養時期轉變為繁殖時期的過程。由經典的嫁接實驗發現,植物在接收到日照長短的改變之後,開花激素(刺激開花的物質),會在葉部生成,並且經由韌皮部長距離移動到植物頂端而誘導開花。先前的研究已經發現FLOWERING LOCUS T (FT)的蛋白質可在阿拉伯芥以及稻米中扮演類開花激素的角色。然而,當FT 蛋白質與其結合物形成複合體而侷限在維管束內時,植物開花的時間並沒有因此而延遲,顯示可能有其他扮演類開花激素的物質誘導開花的起始,推測FT 的訊息核醣核酸可能扮演誘導功能。因此,在本研究當中,利用反轉錄聚合酶鏈反應,我們首先確定了FT 的訊息核醣核酸的確存在於Brassica oleracea(一種和阿拉伯芥相當接近的物種)的韌皮部汁液中。藉著阿拉伯芥的嫁接實驗更進一步的確認了FT 訊息核醣核酸的長距離移動。本研究結果顯示,除了已被報導不具長距離移動能力的FT-EGFP 片段之外,帶著標定片段的FT 訊息核醣核酸,確實可以移動穿越嫁接的單元而被偵測到。除此之外,FT 訊息核醣核酸長距離移動和促進開花之間有正相關的關係。綜合以上,我們提出FT 的訊息核醣核酸和蛋白質可並行扮演開花激素而調節開花的時間。

    In higher plants, the determination of the transition from vegetative to reproductive stage is one of the most important steps during their developmental courses. In order to produce offspring at optimal environmental conditions, plants must response to the variations of ambient condition and adjust their reproductive transition. From classic grafting experiments, it has been established that after plants receiving day-length difference, florigen, the floral stimuli, are synthesized in the leaves and then transported long-distance through phloem to trigger flowering at apices. Previous studies have shown that the protein of FLOWERING LOCUS T (FT) may act as a florigen-like molecule in Arabidopsis and rice. However, while FT protein movement is restricted by expressing a strong FT-binding protein in vascular tissues, the flowering time is not delayed, suggesting that other florigen-like molecule, probably FT mRNA, may act redundantly to trigger floral initiation. To test this
    possibility, we first determined the existence of FT mRNA in the phloem sap. By using RT-PCR analysis, FT mRNA is detected in the phloem sap collected from Brassica oleracea, a species closely related to Arabidopsis. To further test the long-distance movement of FT mRNA, the Arabidopsis grafting experiments were conducted. Our results show that the chimeric FT mRNA except FT-EGFP can move long-distance trough grafting unit. In addition, the
    detection of FT mRNA in the scion apices is well correlated with the floral promotion in the scions. Taken together, we propose that both FT mRNA and protein may act redundantly as florigens to regulate flowering time.

    Introduction ................................................................................................................1 1.1 The florigen is a general floral stimulus among diverse plant species.....................................................................................................1 1.2 mRNA may act as a long-distance information molecule ..........2 1.3 Florigen is possibly generated in long-day pathway, down-stream of CONSTANS ..............................................................3 1.4 The investigation of FT as florigen ..................................................4 1.5 Specific Aim............................................................................................6 Materials and Methods ............................................................................................7 3.1 Plant materials and growth conditions ...........................................7 3.2 Construction and transgenic plants generation...........................7 3.3 Broccoli phloem sap collection ........................................................8 3.4 Arabidopsis inflorescence grafting assay .....................................8 3.5 Seedling grafting assay.......................................................................9 3.6 RNA extraction.......................................................................................9 3.7 Reverse transcription polymerase chain reaction (RT-PCR) ..10 3.8 Confocal microscopy.........................................................................11 Results .......................................................................................................................12 2.1 FT mRNA can be detected in the phloem sap of broccoli .......12 2.2 The movement of chimaric FT mRNA can be detected by inflorescence grafting assay............................................................12 2.3 The 3’UTR may play a role in stabilizing FT mRNA...................14 2.4 The distribution of EGFP-FT fusion protein is ubiquitous in the root tissues...........................................................................................15 2.5 Wild-type FT mRNA is non-detectable in inflorescence grafting assay......................................................................................................16 Discussion ................................................................................................................18 4.1 Long-distance movement of FT mRNA.........................................18 4.2 The diversity of long-distance transportation in plants ...........19 4.3 The distribution of SUC2: EGFP-FT protein suggests the possibility of protein movement.....................................................20 4.4 Auto-regulation may play a role in flowering regulation..........21 Table 1. Flowering time of all transgenic plants.............................................26 Figures .......................................................................................................................23 References................................................................................................................36 Appendix I. Primers used in this study.............................................................41

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