Team:Caltech/Project/Results

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To determine the expression logic of the combinatorial promoters that we used, DH5&alpha-Z1 cells that were transformed with our test constructs were grown for about 8 hours in MOPS media with different inducer concentrations, and then GFP fluorescence of these cells were measured (see <a href="https://2014.igem.org/Team:Caltech/Project/Experiments">"The Experiments"</a>). We found that the A90 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369000">BBa_K1369000</a>) acted as an AND-gate, the B83 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369001">BBa_K1369001</a>) acted as an asymmetric-AND gate, and the D46 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369002">BBa_K1369002</a>) acted as a single-input gate. These results were consistent with the findings reported by Robert Sidney Cox <i>et al</i>.  
To determine the expression logic of the combinatorial promoters that we used, DH5&alpha-Z1 cells that were transformed with our test constructs were grown for about 8 hours in MOPS media with different inducer concentrations, and then GFP fluorescence of these cells were measured (see <a href="https://2014.igem.org/Team:Caltech/Project/Experiments">"The Experiments"</a>). We found that the A90 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369000">BBa_K1369000</a>) acted as an AND-gate, the B83 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369001">BBa_K1369001</a>) acted as an asymmetric-AND gate, and the D46 promoter construct (<a href="http://parts.igem.org/Part:BBa_K1369002">BBa_K1369002</a>) acted as a single-input gate. These results were consistent with the findings reported by Robert Sidney Cox <i>et al</i>.  
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[[Image:JwAA001_heatmap.png|thumb|center|500px| Heatmap of mean GFP fluorescence (au) as regulated by this RR promoter in vivo. Cells were grown for around 8 hours with various inducer concentrations before measurements were taken]]
 
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[[Image:JwAA001_barchart.png|thumb|950 px|Barchart of mean GFP fluorescence (au) as regulated by this RR promoter in vivo. This barchart was obtained using the same data that generated the above heatmap.]]
 
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<img src="http://parts.igem.org/File:08082014_tbAA002_heatmap.png" width="500 px">
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<center><img src="http://parts.igem.org/File:08082014_tbAA002_heatmap.png" width="500 px">
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<img src="http://parts.igem.org/File:08082014_tbAA002_barchart.png" width="500 px">
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<img src="http://parts.igem.org/File:08082014_tbAA002_barchart.png" width="500 px"></center>

Revision as of 19:32, 14 October 2014



Home Team Official Team Profile Project Parts Modeling Notebook Safety Attributions
Results
Project Overview

Project Details

Materials and Methods

The Experiments

Results

Data Analysis

Conclusions

References

Testing Export of Signaling Ligands

Western Blots

To determine whether or not the signaling ligands in these quorum sensing systems are exported, we Western blotted both the supernatant and cell lysate from cell cultures expressing the constructs we named pTG004 and pTG005 (lam system with 3xFLAG at the N-terminus of the lamD prepeptide sequence, and fsr system with 3xFLAG at the N-terminus of the GBAP domain within the fsrB protein sequence, respectively). The results are shown in Figure 1 and Figure 2 below.



Figure 1. Western Blot – Cell Lysate Liquid cultures of cells expressing the lam and fsr export systems and induced with aTc were spun down and lysed before running the Western blot on the lysate samples. Only the samples originating from cells expressing the fsr system (pTG005) appeared to have even produced proteins with the 3xFLAG in the domain. Samples’ levels of aTc induction are indicated above their respective lanes.



Figure 2. Western Blot – Supernatant Liquid cultures of cells expressing the lam and fsr export systems and induced with aTc were spun down, and the Western blot was run on the supernatant. Only the samples originating from originating from cells expressing the fsr system (pTG005) appeared to have exported proteins with a 3xFLAG domain within them. The gel ran crooked, making the size of the smallest fragment uncertain. Samples’ levels of aTc induction are indicated above their respective lanes.

After running the Western blots, we observed multiple bands in both the supernatant and cell lysate for the samples originating from cells expressing the fsr quorum sensing system, offering promise that the GBAP signaling ligand is synthesized and exported. The bands observed appeared indicate the presence of proteins roughly 30 kDa, 25 kDa, and 5 kDa in size both in the supernatant and in the cell lysate. The 30 kDa fragment appears to correlate to entire, uncleaved fsrB membrane protein (see Figure 2 in "The Experiments"), while the 25 kDa fragment appears to correlate to the cleaved membrane-bound component of fsrB (the third fragment). Due to the faintness of the Western C ladder in the cell lysate blot and the crookedness of the supernatant blot, it was difficult to ascertain the size of the smallest band present in the fsr samples, but it is hypothesized to be close to 5 kDa, which, would suggest it is the GBAP signaling molecule with the 3xFLAG, and possibly the remainder of the fsrB membrane protein, attached to it (the last two fragments). While the presence of bands in the Westerns demonstrates that the fsr export system’s genes are being expressed in E. coli, the presence of large bands in the supernatant as well is troublesome, since those bands should correspond to fragments still embedded in the membrane and should have been pelleted and not present in the supernatant. It is possible that some cells were not fully spun down, and so the fsrB fragments embedded in their membranes were still present in the supernatant sample.

In contrast, no bands at all appeared on the Western blot for samples originating from cells expressing the lam system. This indicates that, barring some experimental error, none of the fragments detailed in Figure 1 (in "The Experiments") were synthesized by the cells, much less exported, suggesting that the ligand synthesis and export components of the lam QS system is incapable of being implemented in E. coli.


Liquid Chromatography/Mass Spectroscopy

Additionally, to test for presence of the signaling ligands, supernatants of liquid cell cultures expressing our constructed plasmids were analyzed for the presence of signaling ligand using liquid chromatography mass spectroscopy. Due to time constraints, we were able to test only cell cultures expressing an unflagged variant of pTG004 (the lam QS system). We removed the 3xFLAG domain from pTG004 by linearizing pTG004 without the 3xFLAG via PCR with the appropriate primers and then recircularizing the plasmid via a round-the-horn reaction. Cell cultures carrying the unflagged pTG004 were then grown in MOPS media under 250 nM aTc induction and then spun down to collect the supernatant, which was run through a filtration column to isolate the signaling ligand. The resulting sample was then analyzed by LC/MS. As mentioned in the "The Experiment" section, strong peaks were expected to be seen at m/z ratios of 260.1, 345.2, 373.2, and 577.3 after roughly 27 minutes flowing through the column (at a flow rate of 0.2 mL/min). We did not observe these peaks in our data (see Figure 3 and Figure 4), and the only peaks observed in our experimental sample with 250 nM aTc induction (data in Figure 3) were also present in our negative control grown without aTc induction (data in Figure 4), corresponding to background signal probably from the growth media. Since there did not appear to exist any significant peaks present in the induced sample but not in the negative control (the LC/MS plots for the induced sample were nearly identical to those for the uninduced sample), these data support the conclusion obtained from our Western blot experiment that the lam system is unable to synthesize and export its signaling peptide in E. coli.



Figure 3. Unflagged lam-Expressing Cell Supernatant with 0 nM aTc Induction At charge-to-mass ratios of 577.3 and 260.1, no notable peaks were observed, and the overall signal was noisy. At m/z of 373.2, a significant peak was noticed at 3.31 minutes. At m/z of 345.2, significant peaks were observed at 1.13 and 3.31 minutes.



Figure 4. Unflagged lam-Expressing Cell Supernatant with 250 nM aTc Induction At charge-to-mass ratios of 577.3 and 260.1, no notable peaks were observed, and the overall signal was noisy. Significant peaks were noticed at 3.31 minutes for m/z of 373.2 and 1.12 and 3.32 minutes for m/z of 345.2. However, no notable peaks were noticed at ~13 minutes at any of the expected m/z ratios (within the marked red box), making this graph nearly identical to that for the negative control (Figure 3).


Testing Signaling Ligand Reception


Testing Combinatorial Promoter Logic

To determine the expression logic of the combinatorial promoters that we used, DH5&alpha-Z1 cells that were transformed with our test constructs were grown for about 8 hours in MOPS media with different inducer concentrations, and then GFP fluorescence of these cells were measured (see "The Experiments"). We found that the A90 promoter construct (BBa_K1369000) acted as an AND-gate, the B83 promoter construct (BBa_K1369001) acted as an asymmetric-AND gate, and the D46 promoter construct (BBa_K1369002) acted as a single-input gate. These results were consistent with the findings reported by Robert Sidney Cox et al.