Team:Austin Texas/interlab study

From 2014.igem.org

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<h1>Interlab Study</h1>
<h1>Interlab Study</h1>
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The interlab study is a new feature of iGEM this year.  As part of the measurement track, we participated in the interlab study as described on the [https://2014.igem.org/Tracks/Measurement/Interlab_study Interlab Study page].  The purpose of this study was to measure the fluorescence of three different devices, two of which we constructed in lab from biobrick parts.  The third device was simply a plasmid included in the 2014 parts kit.  Below, we detail our Interlab Study experience and discuss what our findings could mean.
The interlab study is a new feature of iGEM this year.  As part of the measurement track, we participated in the interlab study as described on the [https://2014.igem.org/Tracks/Measurement/Interlab_study Interlab Study page].  The purpose of this study was to measure the fluorescence of three different devices, two of which we constructed in lab from biobrick parts.  The third device was simply a plasmid included in the 2014 parts kit.  Below, we detail our Interlab Study experience and discuss what our findings could mean.
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*The next morning, add 10µL of each overnight culture to 10 mL of LB with three replicates of each (15 total flasks) and grow 16-18 hours at 37°C, shaking at 300rpm.  Triplicate cultures were continued.
*The next morning, add 10µL of each overnight culture to 10 mL of LB with three replicates of each (15 total flasks) and grow 16-18 hours at 37°C, shaking at 300rpm.  Triplicate cultures were continued.
*After 16-18 hours, add 80 µL of each culture to the wells of a clear-bottomed black 96-well plate.
*After 16-18 hours, add 80 µL of each culture to the wells of a clear-bottomed black 96-well plate.
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<h3>Measurement Protocol</h3>
<h3>Measurement Protocol</h3>
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<h1>Sequencing Data</h1>
<h1>Sequencing Data</h1>
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After sequencing our constructs, we aligned them to the reference part sequences.
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After sequencing our constructs, we aligned them to the reference part sequences. '''While constructs 1 and 2 were consistent with the references, we were surprised to see two point mutations in construct 3.''' This seemed highly unlikely to have occurred by chance. As such, we consulted the parts registry and found that the [http://parts.igem.org/cgi/sequencing/one_blast.cgi?id=21282 sequence analysis of the spring 2014 plate] shows two point mutations consistent with our sequence reads.
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While constructs 1 and 2 were consistent with the references, we were surprised to see two point mutations in construct 3. This seemed highly unlikely to have occurred by chance. As such, we consulted the parts registry and found that the [http://parts.igem.org/cgi/sequencing/one_blast.cgi?id=21282 sequence analysis of the spring 2014 plate] shows two point mutations consistent with our sequence reads.
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[https://2014.igem.org/Team:Austin_Texas/interlab_study/sequences/I20260 Sequence of construct BBa_I20260]<br>
[https://2014.igem.org/Team:Austin_Texas/interlab_study/sequences/I20260 Sequence of construct BBa_I20260]<br>
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[[File:interlabchartminimal.png|440px|right|thumb| '''Figure 2.'''  Relative fluorescence data for the three parts measured.]]
[[File:interlabchartminimal.png|440px|right|thumb| '''Figure 2.'''  Relative fluorescence data for the three parts measured.]]
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Data was collected using Infinite 200 PRO Microplate Reader and a 96 well black plate with 80 µl of culture per well.  As shown in Figure 2, we used triplicate cultures and took averages of each set to represent the measured relative fluorescence of the part. Our representation of the data subtracts the fluorescence of the media background from the GFP signal, and then is divided by the OD<sub>600</sub> of the cell culture with the OD<sub>600</sub> of the media subtracted, or (GFP-LB<sub>bkgd</sub>)/(OD<sub>600</sub>-OD<sub>600</sub>LB<sub>bkgd</sub>).
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Data was collected using an Infinite 200 PRO Microplate Reader and a 96-well black plate with 80 µl of culture per well.  As shown in Figure 2, we used triplicate cultures and took averages of each set to represent the measured relative fluorescence of the part. Our representation of the data subtracts the fluorescence of the media background from the GFP signal, and then is divided by the OD<sub>600</sub> of the cell culture with the OD<sub>600</sub> of the media subtracted, or (GFP&minus;LB<sub>bkgd</sub>)/(OD<sub>600</sub>&minus;OD<sub>600</sub>LB<sub>bkgd</sub>).
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Despite the genetic similarities in the devices—all three contained the same coding sequence, two devices had the same backbone and two devices had the same promoter sequence—there were stark differences in the amount of fluorescence produced by each of the devices.
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Despite the genetic similarities in the devices—all three contained the same coding sequence, two devices had the same backbone, and two devices had the same promoter sequence—there were stark differences in the amount of fluorescence produced by each of the devices.
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<h2>Discussion on Unexpected Results</h2>
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<h2>Discussion of Unexpected Results</h2>
While we expected the device with a strong promoter and the highest copy number plasmid to have the highest fluorescence, we did not observe this to be the case. Instead, we saw that the two constructs with the same promoter and coding region in both the medium copy number plasmid pSB3K3 and the high copy number plasmid pSB1C3 actually yielded the strongest fluorescence signal in the medium copy number plasmid. It is possible that the high copy number plasmid pSB1C3 had a negative effect on overall fluorescence—perhaps it became toxic or slowed cell growth.  However, it is also possible that we may have swapped cultures or mislabeled an initial eppendorf or culture tube.
While we expected the device with a strong promoter and the highest copy number plasmid to have the highest fluorescence, we did not observe this to be the case. Instead, we saw that the two constructs with the same promoter and coding region in both the medium copy number plasmid pSB3K3 and the high copy number plasmid pSB1C3 actually yielded the strongest fluorescence signal in the medium copy number plasmid. It is possible that the high copy number plasmid pSB1C3 had a negative effect on overall fluorescence—perhaps it became toxic or slowed cell growth.  However, it is also possible that we may have swapped cultures or mislabeled an initial eppendorf or culture tube.
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In comparing constructs #1 and #3 (with the same coding sequence and plasmid backbone but different promoters), it should be noted that the sequence of promoter J23115 (device #3) differed by two bases from the reference sequence in the registry. While the sequence we used is consistent with the Spring 2014 Kit Distribution sequence analysis performed by the Biobricks Foundation, it is likely that this mutated promoter may have a different activity than the reference sequence. We observed that J23101 (device #1) shows a several-fold stronger signal than our mutated promoter J23115. While the [http://parts.igem.org/Promoters/Catalog/Anderson measured relative fluorescence data] of the reference sequences generally agree with our data, the mutated J23115 shows slightly less activity compared to the reference data. The relative qualitative fluorescence of the cultures can be compared visually (Fig. 1) by looking at the top and bottom rows: the top row using promoter J23101 and the bottom row using mutated promoter J23115, both in pSB1C3.
In comparing constructs #1 and #3 (with the same coding sequence and plasmid backbone but different promoters), it should be noted that the sequence of promoter J23115 (device #3) differed by two bases from the reference sequence in the registry. While the sequence we used is consistent with the Spring 2014 Kit Distribution sequence analysis performed by the Biobricks Foundation, it is likely that this mutated promoter may have a different activity than the reference sequence. We observed that J23101 (device #1) shows a several-fold stronger signal than our mutated promoter J23115. While the [http://parts.igem.org/Promoters/Catalog/Anderson measured relative fluorescence data] of the reference sequences generally agree with our data, the mutated J23115 shows slightly less activity compared to the reference data. The relative qualitative fluorescence of the cultures can be compared visually (Fig. 1) by looking at the top and bottom rows: the top row using promoter J23101 and the bottom row using mutated promoter J23115, both in pSB1C3.
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Revision as of 23:16, 17 October 2014