Revision as of 13:20, 28 October 2017

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Interlab Study: The Results

BioBricks used: BBa_I20270, BBa_R0040, BBa_J36000, BBa_J36001, BBa_J36002, BBa_J36003, BBa_J36004, BBa_J36005

Overview

The iGEM InterLab Study is the currently the largest interlaboratory study in synthetic biology (Beal et al., 2016). The interlab study investigates the replicability of data by providing all participating iGEM teams with protocols for measuring the fluorescence output of a set of genetic devices that have been designed to provide varying levels of Green Fluorescent Protein (GFP) expression. Team Newcastle 2017 followed the Interlab plate reader protocol, which can be found here (link protocol document).

InterLab Measurement Kit

This year, teams were provided with the InterLab Measurement Kit containing fluorescein and LUDOX stocks, along with the devices stored in the Distribution kits. The devices are:

A positive control: BBa_I20270
A negative control: BBa_R0040
Test Device 1: BBa_J36000 (J23101.BCD2.E0040.B0015)
Test Device 2: BBa_J36001 (J23106.BCD2.E0040.B0015)
Test Device 3: BBa_J36002 (J23117.BCD2.E0040.B0015)
Test Device 4: BBa_J36003 (J23101+I13504)
Test Device 5: BBa_J36004 (J23106+I13504)
Test Device 6: BBa_J36005 (J23117+I13504)

Protocols

OD600 Reference Point

LUDOX-HS40 was used as a single point reference to obtain a radiometric conversion factor to convert absorbance data into a standard OD600 measurement. The Reference OD600 divided by the Abs600 from four replicates of LUDOX was used to obtain a correction factor for use against the cell based assays.

Fluorescein Standard Curve

A dilution series of fluorescein in four replicates was prepared and measured in the plate reader to obtain a standard curve of fluorescence for fluorescein concentration. This was used to correct cell-based readings to an equivalent fluorescein concentration, and to then convert this to a GFP concentration.

Plate Reader

Competent E. coli DH5α cells were transformed with each of the devices and plated onto LB+Chl agar, and two colonies from each transformation plate were grown overnight in 10 ml LB + Chl in 50 ml Falcon tubes. Protocols for making competent cells and cell transformation can be found here (link to protocol). Fluorescence was measured as specified in the InterLab protocol on a Synergy H1 plate reader.

Results

Raw results can be found here

Figure 1 InterLab results – (A) Growth, (B) fluorescence and (C) calculated µM fluorescein/OD600 of InterLab devices grown at 37°C in LB for 6 h. Measurements from 4 individual plate readings at 0, 2, 4 and 6 h.

Bacterial growth - We found that the negative control, Tests 3, 5 and 6 grew the most in the 6 h experiment, with the positive control and Test 2 growing less so. Test 1 had the least growth.

Fluorescence - Test 2 showed the most fluorescence after 6 h, with Test 4 showing slightly less, followed closely by the positive control, then Tests 1 and 5. Tests 3 and 6 showed very little fluorescence.

FL/OD - Test 1 gave a significantly higher overall uM fluorescein/OD600 ratio compared to all other devices with values of 0.91 and 0.94 from the separate isolates, compared to a range of <0.01 and 0.18 from all other devices.

Variability - As part of the Interlab study, we analysed two separate bacterial transformants in quadruplicate. This allows an examination of the variability between replicates and between colonies. Between replicates, variation was minimal. However, between colonies containing the same device we saw a degree of variability in growth and fluorescence, thus affecting FL:OD. Figure 2 shows high levels of variability between max OD and Abs measurements of Tests 2 and 4. Fluorescence and subsequently FL:OD are directly affected by growth, but factors including inaccuracies in growth set up and the user taking the samples could have also affected these. As plasmid copy number will not be equal, this will also manifest in readings over time.

Figure 2 Box and whisker plots of (A) max OD and (B) Absorbance values for fluorescence. Maximum values were obtained from all colonies and replicates for each device.

Conclusions and Future Work

After carrying out the InterLab Study we decided to take a high, medium and low expressing device and analyse their sensitivity to changes in environmental conditions. We also looked into how automation could reduce variation between results.

References

Beal, J. et al. (2016) ‘Reproducibility of Fluorescent Expression from Engineered Biological Constructs in E. coli’, PLOS ONE. Edited by D. D. Jones. ACM, 11(3), p. e0150182. doi: 10.1371/journal.pone.0150182.

Interlab Study Improvements: The Results

BioBricks used: BBa_J36001, BBa_J36004, BBa_J36005

Rationale and Aim

Text goes here.

Background Information

Text goes here.

Interlab Devices in Different Contexts

We looked at the impact of temperature, pH and media on how high, medium and low expressing devices performed. Tests 2, 5 and 6 were selected from the Interlab Study after initial results were analysed. Single colonies of each transformant were selected and grown in LB+Chl, then washed and diluted to an OD600 of 0.05 in 100 ul media. Transformants were analysed in quadruplicate, with bacteria and media pipetted onto the plate using a pipetting robot for maximum accuracy. Once set up, the plate was incubated at specified temperatures in a plate reader with double orbital shaking, taking readings every 10 min for 24 h.

Temperature

Growth in Test 2 was affected differently in LB and SOC (Fig 3). In LB, there appears to be a slight increase in max OD reached as temperature increases, however at an alkaline pH the device appears unable to grow well in higher temperatures. In SOC, there is no distinct pattern in how temperature affects growth, however it is clear that the bacteria grows better as pH is increased, suggesting pH and temperature have a combined effect.

Figure 3 Max OD reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.

Fluorescence levels were affected differently at different pH levels as temperature was increased (Figure 4). 37C appears to be optimum temperature for both media, as there are decreases between 37C and 43C at all pH levels apart from pH 7.20 in LB media. However, we can see a dramatic increase in overall max fluorescence levels in both LB and SOC when pH is increased to an alkaline level.

Figure 4 Max fluorescence reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.

pH

Growth was affected significantly by changes in pH, which can be seen in figure 3. In SOC media, a distinct increase is seen in max OD as pH increases. In LB media the opposite is seen, where as pH increases, max growth decreases (figure 6).

Figure 5 Max OD reached by (A) Test 6, (B) Test 5 and (C) Test 2 in SOC media over 24 h at 31C, 37C and 43C.

Figure 6 Max OD reached by Test 5 in LB media over 24 h

Fluorescence was affected by pH particularly in SOC where an increase was seen with an increase in pH; In LB there was little change in fluorescence until an alkaline pH was reached at 43C, where there was a substantial decrease (figure 7).

Figure 7 Max FL reached by Test 2 in (A) SOC and (B) LB media over 24 h

Overall, it is clear pH and temperature have an impact on the growth and fluorescence of the devices, and this raises the importance of maintaining conditions specified in InterLab instructions. It is difficult to draw definite conclusions without more thorough experimentation. It should also be noted that whilst each replicate of isolates was added to the plate using a robot for maximum accuracy, there was still a degree of variability. These variances will have increased over time, and the InterLab method of taking samples at specific time points may be more laborious, but will yield a more accurate result of overall culture behaviour.

Standard Assembly Methods

Text goes here.

Standard Measurement Methods

Text goes here.

Internal Controls

Text goes here.

Robust Promoter Characterisation

Text goes here.

Conclusions and Future Work

Text goes here.

References

Text goes here.

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-</tr>
-<tr>
-<td>
-<div id="interlab_box" class="info_box">
-<h5>Interlab Study: The Results</h5>
-<br />
-<h4>BioBricks used: <a href="http://parts.igem.org/Part:BBa_I20270">BBa_I20270</a>, <a href="http://parts.igem.org/Part:BBa_R0040">BBa_R0040</a>, <a href="http://parts.igem.org/Part:BBa_J364000">BBa_J36000</a>, <a href="http://parts.igem.org/Part:BBa_J364001">BBa_J36001</a>, <a href="http://parts.igem.org/Part:BBa_J364002">BBa_J36002</a>, <a href="http://parts.igem.org/Part:BBa_J364003">BBa_J36003</a>, <a href="http://parts.igem.org/Part:BBa_J364004">BBa_J36004</a>, <a href="http://parts.igem.org/Part:BBa_J364005">BBa_J36005 </a><br /></h4>
-<!--- Link all biobricks used. State whether they are our new bricks or current bricks and give the team name that originally submitted it. -->
-<h7>Overview</h7> <br />
-<!--- Why was this done? what problem is it addressing? How does it address that problem? How does it fit into the rest of the project? What were the aims for this? --->
-<p>
-The iGEM InterLab Study is the currently the largest interlaboratory study in synthetic biology (Beal <i>et al.</i>, 2016). The interlab study investigates the replicability of data by providing all participating iGEM teams with protocols for measuring the fluorescence output of a set of genetic devices that have been designed to provide  varying levels of Green Fluorescent Protein (GFP) expression. Team Newcastle 2017 followed the Interlab plate reader protocol, which can be found <a href='#'><u>here</u></a> (link protocol document).
-</p>
-<br />
-<h7>InterLab Measurement Kit</h7><br />
-<!--- How was this stage designed? What was its sequence (if it's a part)? Was it modelled? What considerations were taken into account when making it? What challenges were there? How does the design link back to the rationale? (i.e. why does this design work). --->
-<p>
-This year, teams were provided with the InterLab Measurement Kit containing fluorescein and LUDOX stocks, along with  the devices stored in the Distribution kits. The devices are:<br />
--          A positive control: BBa_I20270<br />
--          A negative control: BBa_R0040<br />
--          Test Device 1: BBa_J36000 (J23101.BCD2.E0040.B0015)<br />
--          Test Device 2: BBa_J36001 (J23106.BCD2.E0040.B0015)<br />
--          Test Device 3: BBa_J36002 (J23117.BCD2.E0040.B0015)<br />
--          Test Device 4: BBa_J36003 (J23101+I13504)<br />
--          Test Device 5: BBa_J36004 (J23106+I13504)<br />
--          Test Device 6: BBa_J36005 (J23117+I13504)<br />
-</p>
-<br />
-<h7>Protocols</h7><br />
-<!--- How was this part of the project implemented? How was it assembled if it is a part? How was it prepared for testing? What were the challenges? Why was it implemented in that way (e.g. why was that assembly method chosen)? How was it confirmed as having been implemented/assembled correctly? Include gels, images of plates, sequence data, preliminary information, etc. and refer to the specific sections of the lab-book which document this. --->
-<h6>OD600 Reference Point</h6><br />
-<p>
-LUDOX-HS40 was used as a single point reference to obtain a radiometric conversion factor to convert absorbance data into a standard OD600 measurement. The Reference OD600 divided by the Abs600 from four replicates of LUDOX was used to obtain a correction factor for use against the cell based assays.<br />
-</p>
-<h6>Fluorescein Standard Curve</h6><br />
-<p>
-A dilution series of fluorescein in four replicates was prepared and measured in the plate reader to obtain a standard curve of fluorescence for fluorescein concentration. This was used to correct cell-based readings to an equivalent fluorescein concentration, and to then convert this to a GFP concentration.<br />
-</p>
-<h6>Plate Reader</h6><br />
-<p>
-Competent E. coli DH5α cells were transformed with each of the devices and plated onto LB+Chl agar, and two colonies from each transformation plate were grown overnight in 10 ml LB + Chl in 50 ml Falcon tubes. Protocols for making competent cells and cell transformation can be found here (link to protocol). Fluorescence was measured as specified in the InterLab protocol on a Synergy H1 plate reader.
-</p>
-<br />
-<h7>Results</h7> <br />
-<!-- What experiments were performed? Refer to specific protocols, relevant sections of the lab-book, and provide enough detail that experiments could be carried out by anyone without prior knowledge of the project. Why was each experiment performed? How do they link back to the rationale/aims? What results were expected and what was actually observed? Explain the results with graphs/etc. (include legends) and what each result means. -->
-<p>
-Raw results can be found <a href="https://static.igem.org/mediawiki/2017/8/8a/T--Newcastle--interlabrawresults.pdf"><u>here</u></a>. <br />
-</p>
-<div style="text-align: center;"><img style="width:50%" src="https://static.igem.org/mediawiki/2017/d/de/T--Newcastle--interlabgraph.jpeg"></div>
-<b>Figure 1</b> InterLab results – (A) Growth, (B) fluorescence and (C) calculated µM fluorescein/OD600 of InterLab devices grown at 37°C in LB for 6 h. Measurements from 4 individual plate readings at 0, 2, 4 and 6 h.
-<br />
-<p>
-<b>Bacterial growth.</b> We found that the negative control, Tests 3, 5 and 6 grew the most in the 6 h experiment, with the positive control and Test 2 growing less so. Test 1 had the least growth. <br />
-</p>
-<p>
-<b>Fluorescence.</b> Test 2 showed the most fluorescence after 6 h, with Test 4 showing slightly less, followed closely by the positive control, then Tests 1 and 5. Tests 3 and 6 showed very little fluorescence.<br />
-</p>
-<p>
-<b>FL/OD.</b> Test 1 gave a significantly higher overall uM fluorescein/OD600 ratio compared to all other devices with values of 0.91 and 0.94 from the separate isolates, compared to a range of <0.01 and 0.18 from all other devices. <br />
-</p>
-<p>
-<b>Variability.</b> As part of the Interlab study, we analysed two separate bacterial transformants in quadruplicate. This allows an examination of the variability between replicates and between colonies. Between replicates, variation was minimal. However, between colonies containing the same device we saw a degree of variability in growth and fluorescence, thus affecting FL:OD. Figure 2 shows high levels of variability between max OD and Abs measurements of Tests 2 and 4. Fluorescence and subsequently FL:OD are directly affected by growth, but factors including inaccuracies in growth set up and the user taking the samples could have also affected these. As plasmid copy number will not be equal, this will also manifest in readings over time.<br />
-</p>
-<div style="text-align: center;"><img style="width:80%" src="https://static.igem.org/mediawiki/2017/b/bd/T--Newcastle--interlabODFLvariation.jpg"></div>
-<b>Figure 2</b> Box and whisker plots of (A) max OD and (B) Absorbance values for fluorescence. Maximum values were obtained from all colonies and replicates for each device.
-<br />
-<br />
-<h7>Conclusions and Future Work</h7> <br />
-<!--- Give a quick overview of what this section of the project was, the aims, and to what extent they were achieved. Discuss what further characterisation could be performed and whether anything (e.g. the design of a part) could be modified to improve it. Discuss what the next step would be (e.g. test more variants, repeats, etc.)-->
-<p>
-After carrying out the InterLab Study we decided to take a high, medium and low expressing device and analyse their sensitivity to changes in environmental conditions. We also looked into how automation could reduce variation between results.
-</p>
-<br />
-<h7>References</h7><br />
-<!--- Reference list --->
-Beal, J. <i>et al.</i> (2016) ‘Reproducibility of Fluorescent Expression from Engineered Biological Constructs in E. coli’, <i>PLOS ONE</i>. Edited by D. D. Jones. ACM, 11(3), p. e0150182. doi: 10.1371/journal.pone.0150182.
-</div>
-</td>
-</tr>
-<tr>
-<td>
-<div id="interlab_improv_box" class="info_box">
-<h5>Interlab Study Improvements: The Results</h5>
-<br />
-<h4>BioBricks used: <a href="http://parts.igem.org/Part:BBa_J364001">BBa_J36001</a>, <a href="http://parts.igem.org/Part:BBa_J364004">BBa_J36004</a>, <a href="http://parts.igem.org/Part:BBa_J364005">BBa_J36005</a></h4>
-<!--- Link all biobricks used. State whether they are our new bricks or current bricks and give the team name that originally submitted it. -->
-<h7>Rationale and Aim</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Background Information</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Interlab Devices in Different Contexts</h7>
-<p>
-<br />
-We looked at the impact of temperature, pH and media on how high, medium and low expressing devices performed. Tests 2, 5 and 6 were selected from the Interlab Study after initial results were analysed. Single colonies of each transformant were selected and grown in LB+Chl, then washed and diluted to an OD600 of 0.05 in 100 ul media. Transformants were analysed in quadruplicate, with bacteria and media pipetted onto the plate using a pipetting robot for maximum accuracy. Once set up, the plate was incubated at specified temperatures in a plate reader with double orbital shaking, taking readings every 10 min for 24 h.
-<br />
-</p>
-<p>
-<b>Temperature</b><br />
-Growth in Test 2 was affected differently in LB and SOC (Fig 3). In LB, there appears to be a slight increase in max OD reached as temperature increases, however at an alkaline pH the device appears unable to grow well in higher temperatures. In SOC, there is no distinct pattern in how temperature affects growth, however it is clear that the bacteria grows better as pH is increased, suggesting pH and temperature have a combined effect.
-<br />
-<div style="text-align: center;"><img style="width:80%" src=https://static.igem.org/mediawiki/2017/a/a9/T--Newcastle--ODtempHLBSOC2.jpeg></div><br />
-<b>Figure 3</b> max OD reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.<br />
-</p>
-<br />
-<p>
-Fluorescence levels were affected differently at different pH levels as temperature was increased (Figure 4). 37C appears to be optimum temperature for both media, as there are decreases between 37C and 43C at all pH levels apart from pH 7.20 in LB media. However, we can see a dramatic increase in overall max fluorescence levels in both LB and SOC when pH is increased to an alkaline level.
-</p>
-<div style="text-align: center;"><img style="width:80%" src=https://static.igem.org/mediawiki/2017/8/8a/T--Newcastle--FLtempHLBSOC.jpeg></div><br />
-<b>Figure 4</b> max fluorescence reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.<br />
-</p><br />
-<b>pH</b><br />
-Growth was affected significantly by changes in pH, which can be seen in figure 3. In SOC media, a distinct increase is seen in max OD as pH increases. In LB media the opposite is seen, where as pH increases, max growth decreases (figure 4). </p> <br />
-<div style="text-align: center;"><img style="width:80%" src=https://static.igem.org/mediawiki/2017/7/7b/T--Newcastle--SOCmaxODcorrect.jpeg></div><br />
-<b>Figure 3</b> max OD reached by (A) Test 6, (B) Test 5 and (C) Test 2 in SOC media over 24 h at 31C, 37C and 43C.<br />
-<br />
-<div style="text-align: center;"><img style="width:25%" src=https://static.igem.org/mediawiki/2017/c/c4/T--Newcastle--maxODtest5LBcorrect.jpeg></div><br />
-<b>Figure 4</b> max OD reached by Test 5 in LB media over 24 h<br />
-<p>
-Fluorescence was affected by pH particularly in SOC where an increase was seen with an increase in pH; In LB there was little change in fluorescence until an alkaline pH was reached at 43C, where there was a substantial decrease (figure 5).<br />
-<div style="text-align: center;"><img style="width:50%" src=https://static.igem.org/mediawiki/2017/8/80/T--Newcastle--maxFLSOCLB.jpeg></div><br />
-<b>Figure 5</b> max FL reached by Test 2 in (A) SOC and (B) LB media over 24 h<br />
-</p>
-<br />
-<p>
-Overall, it is clear pH and temperature have an impact on the growth and fluorescence of the devices, and this raises the importance of maintaining conditions specified in InterLab instructions. It is difficult to draw definite conclusions without more thorough experimentation. It should also be noted that whilst each replicate of isolates was added to the plate using a robot for maximum accuracy, there was still a degree of variability. These variances will have increased over time, and the InterLab method of taking samples at specific time points may be more laborious, but will yield a more accurate result of overall culture behaviour.
-</p>
-<br />
-<h7>Standard Assembly Methods</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Standard Measurement Methods</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Internal Controls</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Robust Promoter Characterisation</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>Conclusions and Future Work</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-<h7>References</h7>
-<p>
-<br />
-INSERT TEXT HERE
-<br />
-</p>
-</div>
-</td>
-</tr>
-<table>
-</div>
+    <div  class="container-fluid" id="main" style="width: 100%; padding-top: 0.5%">
+    <div class="container-fluid" style="max-width: 60%">
+      <h1 style="font-family: Rubik">Interlab Study: The Results</h1>
+      <p class = "text-left" style="font-family: Rubik; font-size: 0.7em">BioBricks used: <a href="http://parts.igem.org/Part:BBa_I20270">BBa_I20270</a>, <a href="http://parts.igem.org/Part:BBa_R0040">BBa_R0040</a>, <a href="http://parts.igem.org/Part:BBa_J364000">BBa_J36000</a>, <a href="http://parts.igem.org/Part:BBa_J364001">BBa_J36001</a>, <a href="http://parts.igem.org/Part:BBa_J364002">BBa_J36002</a>, <a href="http://parts.igem.org/Part:BBa_J364003">BBa_J36003</a>, <a href="http://parts.igem.org/Part:BBa_J364004">BBa_J36004</a>, <a href="http://parts.igem.org/Part:BBa_J364005">BBa_J36005 </a></p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Overview </h2>
+      <p>The iGEM InterLab Study is the currently the largest interlaboratory study in synthetic biology (Beal et al., 2016). The interlab study investigates the replicability of data by providing all participating iGEM teams with protocols for measuring the fluorescence output of a set of genetic devices that have been designed to provide varying levels of Green Fluorescent Protein (GFP) expression. Team Newcastle 2017 followed the Interlab plate reader protocol, which can be found here (link protocol document).</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">InterLab Measurement Kit</h2>
+      <p>This year, teams were provided with the InterLab Measurement Kit containing fluorescein and LUDOX stocks, along with the devices stored in the Distribution kits. The devices are:</p>
+      <ul>
+        <li>A positive control: BBa_I20270</li>
+        <li>A negative control: BBa_R0040</li>
+        <li>Test Device 1: BBa_J36000 (J23101.BCD2.E0040.B0015)</li>
+        <li>Test Device 2: BBa_J36001 (J23106.BCD2.E0040.B0015)</li>
+        <li>Test Device 3: BBa_J36002 (J23117.BCD2.E0040.B0015)</li>
+        <li>Test Device 4: BBa_J36003 (J23101+I13504)</li>
+        <li>Test Device 5: BBa_J36004 (J23106+I13504)</li>
+        <li>Test Device 6: BBa_J36005 (J23117+I13504)</li>
+      </ul>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Protocols</h2>
+      <h4 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">OD600 Reference Point</h4>
+      <p>LUDOX-HS40 was used as a single point reference to obtain a radiometric conversion factor to convert absorbance data into a standard OD600 measurement. The Reference OD600 divided by the Abs600 from four replicates of LUDOX was used to obtain a correction factor for use against the cell based assays.</p>
+      <h4 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Fluorescein Standard Curve</h4>
+      <p>A dilution series of fluorescein in four replicates was prepared and measured in the plate reader to obtain a standard curve of fluorescence for fluorescein concentration. This was used to correct cell-based readings to an equivalent fluorescein concentration, and to then convert this to a GFP concentration.</p>
+      <h4 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Plate Reader</h4>
+      <p>Competent E. coli DH5α cells were transformed with each of the devices and plated onto LB+Chl agar, and two colonies from each transformation plate were grown overnight in 10 ml LB + Chl in 50 ml Falcon tubes. Protocols for making competent cells and cell transformation can be found here (link to protocol). Fluorescence was measured as specified in the InterLab protocol on a Synergy H1 plate reader.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Results</h2>
+      <p>Raw results can be found <a target="_blank" href="https://static.igem.org/mediawiki/2017/8/8a/T--Newcastle--interlabrawresults.pdf">here</a></p>
+      <img src="https://static.igem.org/mediawiki/2017/d/de/T--Newcastle--interlabgraph.jpeg" class="img-fluid border border-dark rounded mx-auto d-block" style="max-width: 50%">
+      <p class="text-center"><b>Figure 1</b> InterLab results – (A) Growth, (B) fluorescence and (C) calculated µM fluorescein/OD600 of InterLab devices grown at 37°C in LB for 6 h. Measurements from 4 individual plate readings at 0, 2, 4 and 6 h.</p>
+      <p style="margin-top:4%"><b>Bacterial growth - </b>We found that the negative control, Tests 3, 5 and 6 grew the most in the 6 h experiment, with the positive control and Test 2 growing less so. Test 1 had the least growth. </p>
+      <p><b>Fluorescence - </b>Test 2 showed the most fluorescence after 6 h, with Test 4 showing slightly less, followed closely by the positive control, then Tests 1 and 5. Tests 3 and 6 showed very little fluorescence.</p>
+      <p><b>FL/OD - </b>Test 1 gave a significantly higher overall uM fluorescein/OD600 ratio compared to all other devices with values of 0.91 and 0.94 from the separate isolates, compared to a range of <0.01 and 0.18 from all other devices. </p>
+      <p><b>Variability - </b>As part of the Interlab study, we analysed two separate bacterial transformants in quadruplicate. This allows an examination of the variability between replicates and between colonies. Between replicates, variation was minimal. However, between colonies containing the same device we saw a degree of variability in growth and fluorescence, thus affecting FL:OD. Figure 2 shows high levels of variability between max OD and Abs measurements of Tests 2 and 4. Fluorescence and subsequently FL:OD are directly affected by growth, but factors including inaccuracies in growth set up and the user taking the samples could have also affected these. As plasmid copy number will not be equal, this will also manifest in readings over time.</p>
+      <img src="https://static.igem.org/mediawiki/2017/b/bd/T--Newcastle--interlabODFLvariation.jpg" class="img-fluid border border-dark rounded mx-auto d-block">
+      <p class="text-center"><b>Figure 2</b> Box and whisker plots of (A) max OD and (B) Absorbance values for fluorescence. Maximum values were obtained from all colonies and replicates for each device. </p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Conclusions and Future Work</h2>
+      <p>After carrying out the InterLab Study we decided to take a high, medium and low expressing device and analyse their sensitivity to changes in environmental conditions. We also looked into how automation could reduce variation between results.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">References</h2>
+      <p class="text-left">Beal, J. et al. (2016) ‘Reproducibility of Fluorescent Expression from Engineered Biological Constructs in E. coli’, PLOS ONE. Edited by D. D. Jones. ACM, 11(3), p. e0150182. doi: 10.1371/journal.pone.0150182.</p>
+      <h1 style="font-family: Rubik; margin-top: 4%">Interlab Study Improvements: The Results</h1>
+      <p class = "text-left" style="font-family: Rubik; font-size: 0.7em">BioBricks used: <a href="http://parts.igem.org/Part:BBa_J364001">BBa_J36001</a>, <a href="http://parts.igem.org/Part:BBa_J364004">BBa_J36004</a>, <a href="http://parts.igem.org/Part:BBa_J364005">BBa_J36005</a></p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Rationale and Aim</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Background Information</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Interlab Devices in Different Contexts</h2>
+      <p>We looked at the impact of temperature, pH and media on how high, medium and low expressing devices performed. Tests 2, 5 and 6 were selected from the Interlab Study after initial results were analysed. Single colonies of each transformant were selected and grown in LB+Chl, then washed and diluted to an OD600 of 0.05 in 100 ul media. Transformants were analysed in quadruplicate, with bacteria and media pipetted onto the plate using a pipetting robot for maximum accuracy. Once set up, the plate was incubated at specified temperatures in a plate reader with double orbital shaking, taking readings every 10 min for 24 h. </p>
+      <h4 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Temperature</h4>
+      <p>Growth in Test 2 was affected differently in LB and SOC (Fig 3). In LB, there appears to be a slight increase in max OD reached as temperature increases, however at an alkaline pH the device appears unable to grow well in higher temperatures. In SOC, there is no distinct pattern in how temperature affects growth, however it is clear that the bacteria grows better as pH is increased, suggesting pH and temperature have a combined effect.</p>
+      <img src="https://static.igem.org/mediawiki/2017/a/a9/T--Newcastle--ODtempHLBSOC2.jpeg" class="img-fluid border border-dark rounded mx-auto d-block">
+      <p class="text-center"><b>Figure 3</b> Max OD reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.</p>
+      <p style="margin-top: 2%">Fluorescence levels were affected differently at different pH levels as temperature was increased (Figure 4). 37C appears to be optimum temperature for both media, as there are decreases between 37C and 43C at all pH levels apart from pH 7.20 in LB media. However, we can see a dramatic increase in overall max fluorescence levels in both LB and SOC when pH is increased to an alkaline level.</p>
+      <img src="https://static.igem.org/mediawiki/2017/8/8a/T--Newcastle--FLtempHLBSOC.jpeg" class="img-fluid border border-dark rounded mx-auto d-block">
+      <p class="text-center"><b>Figure 4</b> Max fluorescence reached by Test 2 in (A) LB and (B) SOC media over 24 h at 31C, 37C and 43C.
+      <h4 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">pH</h4>
+      <p>Growth was affected significantly by changes in pH, which can be seen in figure 3. In SOC media, a distinct increase is seen in max OD as pH increases. In LB media the opposite is seen, where as pH increases, max growth decreases (figure 6).</p>
+      <img src="https://static.igem.org/mediawiki/2017/7/7b/T--Newcastle--SOCmaxODcorrect.jpeg" class="img-fluid border border-dark rounded mx-auto d-block">
+      <p class="text-center"><b>Figure 5</b> Max OD reached by (A) Test 6, (B) Test 5 and (C) Test 2 in SOC media over 24 h at 31C, 37C and 43C.</p>
+      <img src="https://static.igem.org/mediawiki/2017/c/c4/T--Newcastle--maxODtest5LBcorrect.jpeg" class="img-fluid border border-dark rounded mx-auto d-block" style="max-width: 50%">
+      <p class="text-center"><b>Figure 6</b> Max OD reached by Test 5 in LB media over 24 h</p>
+      <p style="margin-top: 2%">Fluorescence was affected by pH particularly in SOC where an increase was seen with an increase in pH; In LB there was little change in fluorescence until an alkaline pH was reached at 43C, where there was a substantial decrease (figure 7).</p>
+      <img src="https://static.igem.org/mediawiki/2017/8/80/T--Newcastle--maxFLSOCLB.jpeg" class="img-fluid border border-dark rounded mx-auto d-block">
+      <p class="text-center"><b>Figure 7</b> Max FL reached by Test 2 in (A) SOC and (B) LB media over 24 h</p>
+      <p style="margin-top: 2%">Overall, it is clear pH and temperature have an impact on the growth and fluorescence of the devices, and this raises the importance of maintaining conditions specified in InterLab instructions. It is difficult to draw definite conclusions without more thorough experimentation. It should also be noted that whilst each replicate of isolates was added to the plate using a robot for maximum accuracy, there was still a degree of variability. These variances will have increased over time, and the InterLab method of taking samples at specific time points may be more laborious, but will yield a more accurate result of overall culture behaviour.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Standard Assembly Methods</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Standard Measurement Methods</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Internal Controls</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Robust Promoter Characterisation</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">Conclusions and Future Work</h2>
+      <p>Text goes here.</p>
+      <h2 class="text-left" style="margin-top: 2%; margin-bottom: 1%; font-family: Rubik">References</h2>
+      <p>Text goes here.</p>
+  </div>
+  </div>
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-<h1>InterLab</h1>
-<h3>Bronze Medal Criterion #4</h3>
-<p><b>Standard Tracks:</b> Participate in the Interlab Measurement Study and/or improve the characterization of an existing BioBrick Part or Device and enter this information on that part's Main Page in the Registry. The part that you are characterizing must NOT be from a 2017 part number range.
-<br><br>
-For teams participating in the <a href="https://2017.igem.org/Competition/InterLab_Study">InterLab study</a>, all work must be shown on this page.
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Difference between revisions of "Team:Newcastle/InterLab"

Revision as of 13:20, 28 October 2017

Interlab Study: The Results

Overview

InterLab Measurement Kit

Protocols

OD600 Reference Point

Fluorescein Standard Curve

Plate Reader

Results

Conclusions and Future Work

References

Interlab Study Improvements: The Results

Rationale and Aim

Background Information

Interlab Devices in Different Contexts

Temperature

pH

Standard Assembly Methods

Standard Measurement Methods

Internal Controls

Robust Promoter Characterisation

Conclusions and Future Work

References