Team:Austin Texas/kit
From 2014.igem.org
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[[File:UT_Austin_2014_Kit_Normalized_GFP_to_RFP_graph.png|thumb|600px|'''Figure 4.''' Graph showing the level of GFP fluorescence relative to RFP fluorescence for each condition. Each pStG plasmid is referred to based on the tRNA synthetase/tRNA pair present in the specific plasmid. Each of these plasmids was then paired with either pFRY or pFRYC and grown in the presence or absence of a specific ncAA. For example, the "3-AminoY-FRYC" and the "3-AminoY-FRY" samples both contain the 3-AminoY synthetase/tRNA pair and both samples were grown in the absence or presence of the ncAA "3-AminoY". Data are presented as the average of three independent cultures. Error bars denote standard deviation.]] | [[File:UT_Austin_2014_Kit_Normalized_GFP_to_RFP_graph.png|thumb|600px|'''Figure 4.''' Graph showing the level of GFP fluorescence relative to RFP fluorescence for each condition. Each pStG plasmid is referred to based on the tRNA synthetase/tRNA pair present in the specific plasmid. Each of these plasmids was then paired with either pFRY or pFRYC and grown in the presence or absence of a specific ncAA. For example, the "3-AminoY-FRYC" and the "3-AminoY-FRY" samples both contain the 3-AminoY synthetase/tRNA pair and both samples were grown in the absence or presence of the ncAA "3-AminoY". Data are presented as the average of three independent cultures. Error bars denote standard deviation.]] | ||
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- | We wanted to test whether the ncAA synthetase/tRNA pairs would incorporate anything besides their amino acid at the amber stop codon (UAG), and that they would in fact incorporate their specific ncAA if it was present. | + | We wanted to test whether the ncAA synthetase/tRNA pairs would incorporate anything besides their amino acid at the amber stop codon (UAG), and that they would in fact incorporate their specific ncAA if it was present. This is essentially the fidelity of each ncAA sythetase/tRNA pair. Fidelity was measured by comparing the production of GFP in cultures containing pStG/pFRY with or without ncAA. In the absence of a ncAA only RFP should be translated, as translation is expected to halt between RFP and GFP at the amber codon on the linker sequence in pFRY. Alternatively, if the corresponding ncAA for pStG is present or if the synthetase/tRNA pair has low fidelity and can misincorporate a different amino acid, translation should continue through the UAG. In this case, RFP and GFP should both be translated. We also tested pStG/pFRYC strains in (+/-) ncAA conditions as a control for what effect the ncAA has on the fluorescence or growth of the cells. These strains should express RFP and GFP in all conditions since pFRYC does not have an amber codon in the linker (Figure 2). However, if the presence of ncAA affects cell growth or fluorescence activity, we will need these controls to determine the extent of the effect. |
- | To determine the change in GFP fluorescence when the ncAA was present, we first had to calculate how much GFP was expressed relative to the RFP, which would give an upper estimate of how much GFP could theoretically be expressed. We first divided both the GFP and RFP levels by the OD 600 of the culture in order to get the per cell fluorescence levels. We then normalized the GFP fluorescence for one culture to its RFP fluorescence so that we could compare the GFP fluorescence levels between cultures. The normalized GFP values were then compared between cultures grown in the presence of ncAA and cultures grown in the absence of ncAA, which would indicate how the level of GFP fluorescence changes when the ncAA is present. When these values were graphed (Figure 4), some synthetase/tRNA pairs such as 4-azidophenylalanine, 3-nitrotyrosine, 3-iodotyrosine, and ortho-nitrobenzyltyrosine resulted in higher GFP fluorescence in the presence of ncAA than in the absence of ncAA, which suggests that those synthetases only incorporated an amino acid if their specific amino acid was present, meaning that they have a high fidelity. However, the other synthetase/tRNA pairs (3-aminotyrosine, L-DOPA, and cyanophenylalanine) did not show a | + | To determine the change in GFP fluorescence when the ncAA was present, we first had to calculate how much GFP was expressed relative to the RFP, which would give an upper estimate of how much GFP could theoretically be expressed. We first divided both the GFP and RFP levels by the OD 600 of the culture in order to get the per cell fluorescence levels. We then normalized the GFP fluorescence for one culture to its RFP fluorescence so that we could compare the GFP fluorescence levels between cultures. The normalized GFP values were then compared between cultures grown in the presence of ncAA and cultures grown in the absence of ncAA, which would indicate how the level of GFP fluorescence changes when the ncAA is present. |
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+ | When these values were graphed (Figure 4), some synthetase/tRNA pairs such as 4-azidophenylalanine, 3-nitrotyrosine, 3-iodotyrosine, and ortho-nitrobenzyltyrosine resulted in higher GFP fluorescence in the presence of ncAA than in the absence of ncAA, which suggests that those synthetases only incorporated an amino acid if their specific amino acid was present, meaning that they have a high fidelity. However, the other synthetase/tRNA pairs (3-aminotyrosine, L-DOPA, and cyanophenylalanine) did not show a difference in GFP fluorescence normalized to RFP fluorescence dependent on the presence of ncAA, indicating that these pairs incorporated other amino acids at the amber codon when their specific ncAA was not present (and perhaps even when it was), and thus have a low fidelity. | ||
<h2>Synthetase Efficiency</h2> | <h2>Synthetase Efficiency</h2> |
Revision as of 17:11, 17 October 2014
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