Team:Manchester/Parts
From 2013.igem.org
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<b><a id="Q3">Analysis</a></b><br> | <b><a id="Q3">Analysis</a></b><br> | ||
The data obtained from the LC-MS was enormous. 2721 metabolites were detected in the samples, and so we filtered this down to the 43 fatty acids and phospholipids incorporating the compounds we were interested in (oleic acid and linoleic acid). A heat map was generated (seen above) showing the abundances of these 43 phospholipids and fatty acids in the 17 samples we run on the LC-MS. From this heatmap the diversity of detected compounds and and high dynamic range can be seen. For the characterisation of our delta 12 desaturase BioBrick construct, a focus on the individual compounds of high intensity was necessary. An example of this can be seen in the bar chart to the left. | The data obtained from the LC-MS was enormous. 2721 metabolites were detected in the samples, and so we filtered this down to the 43 fatty acids and phospholipids incorporating the compounds we were interested in (oleic acid and linoleic acid). A heat map was generated (seen above) showing the abundances of these 43 phospholipids and fatty acids in the 17 samples we run on the LC-MS. From this heatmap the diversity of detected compounds and and high dynamic range can be seen. For the characterisation of our delta 12 desaturase BioBrick construct, a focus on the individual compounds of high intensity was necessary. An example of this can be seen in the bar chart to the left. | ||
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Revision as of 18:51, 4 October 2013
Successful Expression of delta 9 and delta 12 desaturase, and FabA
In order to characterise our biobricks, we made use of the standard parts found in the registry. By inserting the created biobricks BBa_K1027001 and BBa_K1027002 in to BBa_K608002 (a biobrick consisting of a ribosomal binding site and a constitutive promoter), we were able to create a new construct that expressed the delta 9 desaturase and delta 12 desaturase proteins. The constructs are shown above.
Plates
Another piece of evidence suggesting that our constructs were successfully expressing our delta 9 desaturase and delta 12 desaturase enzymes was the size of the colonies grown on the plates. Pictures of the plates are shown below. On the far left is a control plate, with bacteria transformed with BBa_K608002 but with no gene inserted in front of the promoter. To the right of that are our delta 12 colonies. They are much smaller than the control, and even taking 20 hours to grow to that size as opposed to the usual 16 hours. We hypothesise that because delta 12 desaturase is a membrane-bound protein that the E. coli does not normally express, constitutively expressing it could inhibit the bacteria and slow growth. Compare this to fabA on the far right. Looking through the literature, we found that overexpression of fabA results in no significant difference in growth size or speed relative to the wild type strain (Luo et al, 2009). Compared to the control plate, we also found that the colonies grew normally.
Gel Digests
To confirm that our desired genes were in fact within the expression construct mentioned above, we carried out test digests of our ligated plasmids. Happily, when we ran our digests on an agarose gel, we saw all of the bands we would predict from the expected fragments. The gel pictures are on the right.
delta 9 desaturase: Cut with BamHI + EcoRV. Expected bands 1424 bp, 1262 bp, 99 bp.
delta 12 desaturase: Cut with BamHI, XbaI, PstI. Expected bands 2127 bp, 656 bp, 430 bp.
FabA Cut with EcoRV. Expected bands 1429 bp, 1115 bp. Cut with EcoRV, PstI. Expected bands 1153 bp, 1115 bp, 339 bp.
Delta 9 desaturase and delta 12 desaturase enzymes were chosen because their products, when expressed in their host organism (Synechocystis sp. PCC 6803), convert stearic acid into oleic acid, and oleic acid into linoleic acid respectively. Therefore, we fed batches of transformed DH5-alpha with 2 different concentrations of exogenous fatty acid (0.1% and 0.5% stearic acid fed to the delta 9 desaturase batch, and 0.1% and 0.5% oleic acid fed to the delta 12 desaturase batch), left the cultures growing overnight and then harvested the cells.
To analyse the metabolites extracted from both wild-type DH5-alpha and DH5-alpha expressing our delta 9 desaturase and delta 12 desaturase enzymes, we made use of the MIB’s in-house Orbitrap Liquid Chromatography - Mass Spectrometry (LC-MS). This technique was chosen because of its high mass accuracy and sensitivity. Upon analysing the most abundant metabolites extracted from our expression strains and comparing this data with the most abundant metabolites extracted from wild-type, it is apparent that a massive increase in linoleic acid (incorporated in phosphatidylethanolamines, PE) has occurred. This is demonstrated in the two figures directly below. The chromatograms produced for the delta 12 desaturase expression strains are also shown below. There is a clear difference between the wild-type E. coli fed with exogenous substrate compared with the E. coli strains expressing delta 12 desaturase. It is probable that the peak appearing around 7.9 min in the delta 12 desaturase strains is due to phospholipid incorporating 18:2 (9Z, 12Z) - linoleic acid.
The data obtained from the LC-MS was enormous. 2721 metabolites were detected in the samples, and so we filtered this down to the 43 fatty acids and phospholipids incorporating the compounds we were interested in (oleic acid and linoleic acid). A heat map was generated (seen above) showing the abundances of these 43 phospholipids and fatty acids in the 17 samples we run on the LC-MS. From this heatmap the diversity of detected compounds and and high dynamic range can be seen. For the characterisation of our delta 12 desaturase BioBrick construct, a focus on the individual compounds of high intensity was necessary. An example of this can be seen in the bar chart to the left.