Team:UESTC-China/Project

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<strong>Fig.3</strong> Our strategy of cultivate super plant using synthetic biology.
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<strong>Fig.3</strong> Schematic representation of the design strategy of super plant using synthetic biology.
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<p style="color:#1b1b1b;">We construct 11 different vectors including two backbones, six mono-gene expression vectors and three multi-gene expression vectors. The product of <i>HPS</i>, <i>PHI</i>, and <i>FDH</i> are located in chloroplast, while the product of <i>FALDH</i> are located in cytoplasm. We used chloroplast transit peptides to locate these productions of genes. So we constructed different vectors with and without transit peptide. We hope to compare the ability of metabolizing formaldehyde of transgenic tobacco between different transgenic lines. Those genes are inserted into tobacco via Agrobacterium-mediated leaf disk transformation method. At last, after DNA and RT-PCR detection, we got about 30 positive plants for each vector. Then qualitative detection and quantitative detection are used to explore whether our super plants have better ability of absorbing formaldehyde. From the experimental results, we can draw the conclusion that formaldehyde assimilation pathway and oxidative pathway super plant was strongly enhanced, and the super plant has remarkable formaldehyde tolerance and can dramatically reduce the concentration of formaldehyde in the air (Fig. 4). Due to the time limited, the activity of the four key enzymes in the formaldehyde metabolic pathway and whether the transit peptides can make a difference or not are currently being researched. How to let the gene <i>AHA2</i> expresse in tobacco is what our future effort focus on.
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<p style="color:#1b1b1b;">In total, we constructed 11 different vectors, including two backbones, six mono-gene expression vectors and three multi-gene expression vectors. The production of HPS, PHI, and FDH are located in chloroplast, while FALDH is located in cytoplasm. Chloroplast transit peptides were used for the purpose of chloroplast orientation. For comparison, those vectors carrying the genes of HPS, PHI, and FDH without the presence of transit peptide were also constructed. Those genes are inserted into tobacco via Agrobacterium-mediated leaf disk transformation method. By performing DNA and RT-PCR analysis, we got about 30 positive plants for each vector. The formaldehyde absorbance ability of our super plants was explored by both qualitative and quantitative detection. The results showed that our super plants have remarkable increased abilities of formaldehyde tolerance and can dramatically reduce the concentration of air formaldehyde (Fig. 4). Due to the time limitation, the following investigations are under the way: 1) the effect of individual four key enzymes on the metabolic efficiency of formaldehyde; 2) whether the presence of transit peptides can affect the metabolic efficiency of formaldehyde; 3) the expression of the gene AHA2 in tobacco.</p><br/>
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<strong>Fig.4</strong> Phenotype testing of transgenic seedlings and wildtype. A: Before exposure to HCHO. B: Exposure to HCHO for one week. The transgenic seedling is stronger than wildtype after formaldehyde exposure. 20ul 37% HCHO, one week.
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<strong>Fig.4</strong> Fig. 4 Phenotype testing of transgenic seedlings and wild-type on formaldehyde exposure. A: Before exposure to HCHO. B: Exposure to 20 μl 37% HCHO for one week.
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Revision as of 14:47, 17 October 2014

UESTC-China