Team:UESTC-China/Modeling3

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<p style="color:#1b1b1b;">As all the information above concerned, we realized that since the absorption radio <i>η</i> maintains the constant and by enhancing the absorption radio of formaldehyde, the net absorption rate <i>P</i> would be significant increased. It has been proved (<i>Wang, Noguchi et al. 2014</i>) that, the gene AtAHA2 which was transferred into plant cell, can significantly increase the stomata opening. From that, the absorption rate of formaldehyde would be increased. Therefore, the gene AtAHA2 is a key component to intensify the net absorption rate <i>P</i>. From Fig.1, we know that the larger P, the greater stomatal conductance <i>Gs</i>. Thus, we will clone the stomatal regulation gene, AtAHA2, to the expression vector and transfer into plant cell in the future.</p>
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<p style="color:#1b1b1b;">As all the information above concerned, we realized that since the absorption radio <i>η</i> maintains the constant and by enhancing the absorption radio of formaldehyde, the net absorption rate <i>P</i> would be significant increased. It has been proved (<i>Wang, Noguchi et al. 2014</i>) that, the gene AtAHA2 which was transferred into plant cell, can significantly increase the stomata opening. From that, the absorption rate of formaldehyde would be increased. Therefore, the gene AtAHA2 is a key component to intensify the net absorption rate <i>P</i>. From Fig.1, we also found that the larger P, the greater stomatal conductance <i>Gs</i>. Thus, we will clone the stomatal regulation gene, AtAHA2, to the expression vector and transfer into plant cell in the future.</p>
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Revision as of 09:48, 15 October 2014

UESTC-China