In this graph with the Rhl AHL, it can also be seen that there is a somewhat steady state of GFP expression from LuxR. Although there is an imperceptible increasing slope of points across increasing concentration, GFP expression remains fairly consistent.
Another interesting result was the with the sender RpaI. As depicted in the graph below, it shows an almost steady state of GFP production, independent of the concentration of the AHL signal. This might be a useful finding if researchers wanted to use a smaller amount of signal due to limiting resources of RpaI sender. However, it did not show an orthogonal pathway since it did in fact promote GFP expression.
The resulting graph showed a varied fluctuation between GFP expression and increasing AHL concentration. A noticeable observation however is the overall trend seems to be that 1E-14M through 1E-9M concentration has a steady state of GFP expression then increases with increasing concentration.
A fairly interesting result came about in the induction of LuxR with the Tra AHL. There was a steady increase in GFP expression as the AHL concentration increased. This data will be beneficial to researchers looking for a system with a maximum or minimum GFP induction.
F2620 Induced by Sender Supernatants
*What’s new*
The following experiment, F2620 Induced by Sender Supernatants, used F2620 receiver cells being induced by a variety of combinations of senders in supernatant form. The maximum GFP expression was analyzed to understand the effect different percentages of sender supernatant had on the receiver expressing GFP. We redesigned and optimized supernatant induction protocols to produce more reliable and consistent data than last year. First, we tested more concentrations of filtered sender supernatant and were able to create novel transfer functions. In addition to redoing last year’s inductions with the F2620 using single senders, this year we added combinations of two sender supernatant and therefore greatly improved characterization of the receivers and senders.
Test #1 with LuxR: Sender A: LasI, B: EsaI, C: RpaI
The receiver being used for the below results is the Lux receiver. The second set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #1 with LuxR:
In this set of tests with the Lux receiver the results showed that the LasI expressed the highest, EsaI 2nd highest and RpaI 3rd highest. The graphs concluded that the higher the Las and EsaI combination, the higher the overall GFP expression. No combinations pushed the GFP expression higher than any 50% sender alone.
Test #2 with LuxR: Sender A: RhlI, B: CerI, C: AubI
The second set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #2 with LuxR:
This test showed some notable results. As seen clearly in the last graph, the AubI showed a higher expression when mixed with 10% of a second sender (even when that sender was a negative control sender). The 40% AubI mixed with 10% negative sender and the 40% AubI mixed with 10% RhlI both expressed higher than the 50% AubI by itself. This result was confirmed in another test where 40% Aub mixed with 10% EsaI and 40% AubI mixed with 10% CerI both expressed higher than the 50% AubI alone.
Test #3 with LuxR: Sender A: LasI, B: EsaI, C: RpaI
The third set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #3 with LuxR:
In this set of tests with the Lux receiver the results showed that the RpaI expressed the highest, LasI 2nd highest and EsaI 3rd highest. The graphs concluded that the higher the RpaI and LasI combination, the higher the overall GFP expression. No combinations pushed the GFP expression higher than any 50% sender alone.
Test #4 with LuxR: Sender A: AubI, B: EsaI, C: CerI
The fourth set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #4 with LuxR:
This test showed some notable results. As seen clearly in the last graph, the AubI showed a higher expression when mixed with 10% of a second sender (even when that sender was a negative control sender). The 40% AubI mixed with 10% negative sender and the 40% AubI mixed with 10% EsaI both expressed higher than the 50% AubI by itself. This result was confirmed in the previous test #2 with the LuxR (40% Aub mixed with 10% EsaI and 40% AubI mixed with 10% CerI both expressed higher than the 50% AubI alone).
Test #5 with LuxR: Sender A: LuxI, B: BraI, C: RpaI
The fifth set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #5 with LuxR:
In this test there were some results that were not able to be replicated, meaning that there may have been some contamination or other unaccounted for error. The 40% LuxI + 10% negative sender expressed higher than the 50% LuxI alone, this result was not able to be replicated. Again the 40% LuxI + 10% RpaI expressed higher than the 50% LuxI alone but the result was unable to be replicated and lastly the 40% LuxI + 10% BraI expressed higher than the 50% LuxI and again, the result was unable to be replicated.
Test #6 with LuxR: Sender A: LuxI, B: RhlI, C: LasI
The sixth set of senders that was tested is shown below, these are all the combinations and percentages of the AHLs for the test including the controls. Each data point was tested in triplicate. The colors will coordinate with the graphs for each set of tests. The graphs for each set of data will include the overall average GFP signal, the average OD 600 and the normalization of the GFP over the OD 600. The number of data points used made adding individual error bars ineffective as the data was not able to be read. Error was calculated on the controls and added as separate bar graphs below the full data set. There was also Hill curve (trans equations) made that include error/ standard deviation if more information is needed for any notable results.
Results from test #6 with LuxR:
In this set of tests with the Lux receiver the results showed that the LuxI expressed the highest, RhlI 2nd highest and LasI 3rd highest. The graphs concluded that the higher the LuxI combination, the higher the overall GFP expression. No combinations pushed the GFP expression higher than any 50% sender alone.
F2620 Induced by Sender Cells on Agar
