Team:SDU-Denmark/Tour53
From 2013.igem.org
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- | We were capable of producing a standard curve by reacting DMAPP with acid for 2 min (instead of the 60 min specified in the previous study) <b>(Fig. | + | We were capable of producing a standard curve by reacting DMAPP with acid for 2 min (instead of the 60 min specified in the previous study) <b>(Fig. 1)</b>. At this time, we obtained optimal peak detection for standard solutions. We were, however, incapable of detecting isoprene, even in high concentrations of bacterial samples treated with acid. The test was expanded to include acid hydrolyzation for 2, 30, 60 or 90 min, yet we could not detect isoprene, and therefore not detect DMAPP. |
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- | <a class="popupImg alignRight" style="width:300px" href="https://static.igem.org/mediawiki/2013/1/12/SDU2013_Characterization_Dxs_1.png" title="Figure | + | <a class="popupImg alignRight" style="width:300px" href="https://static.igem.org/mediawiki/2013/1/12/SDU2013_Characterization_Dxs_1.png" title="Figure 1 - Isoprene production after 2 min hydrolyzation of standard DMAPP solutions (Sigma-Aldrich). 4M H2SO4 was used to hydrolyze 1 mL solutions containing different DMAPP amounts. The produced isoprene was detected using headspace gas chromatography with flame ionization detector. Measurements are single values and shows linearity from 0-1000 pmol DMAPP. The isoprene detection in the sample containing 0 pmol DMAPP was subtracted from the peak heights."> |
<img src="https://static.igem.org/mediawiki/2013/1/12/SDU2013_Characterization_Dxs_1.png" style="width:300px" /> | <img src="https://static.igem.org/mediawiki/2013/1/12/SDU2013_Characterization_Dxs_1.png" style="width:300px" /> | ||
- | Figure | + | Figure 1. |
</a> | </a> | ||
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- | <a class="popupImg alignRight" style="width:300px" href="https://static.igem.org/mediawiki/2013/6/68/SDU2013_Characterization_Dxs_2.png" title="Figure | + | <a class="popupImg alignRight" style="width:300px" href="https://static.igem.org/mediawiki/2013/6/68/SDU2013_Characterization_Dxs_2.png" title="Figure 2 - Growth curve of dxs devices. Cells were started at OD<sub>600</sub>=0.005 and incubated at 37ºC and 180 rpm. 2 triplicates of MG1655 carrying no vector (WT), empty pSB1C3 vector (pSB1C3), pSB1C3-Plac-dxs(B.subtilis) (BBa_K1088011) (No LacI), pSB1C3-Pcon-lacI-Plac-dxs(B.subtilis) (BBa_K1088027) (LacI(N)), or pSB1C3-Pcon-lacI:LVA-Plac-dxs(B.subtilis) (BBa_K1088013) (LacI(LVA)). At time 2.5 hours one of each triplicate was induced with 1 mM IPTG. No growth change was observed."> |
<img src="https://static.igem.org/mediawiki/2013/6/68/SDU2013_Characterization_Dxs_2.png" style="width:300px" /> | <img src="https://static.igem.org/mediawiki/2013/6/68/SDU2013_Characterization_Dxs_2.png" style="width:300px" /> | ||
- | Figure | + | Figure 2. |
</a> | </a> | ||
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<a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088027">pSB1C3-Pcon-lacI-Plac-dxs <span class="specialWord">(B. subtilis)</span></a>, or | <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088027">pSB1C3-Pcon-lacI-Plac-dxs <span class="specialWord">(B. subtilis)</span></a>, or | ||
- | <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088013">pSB1C3-Pcon-lacI:LVA-Plac-dxs <span class="specialWord">(B. subtilis)</span></a> were started from ONC at time 0 hours, OD<sub>600</sub>=0.005, and grown at 37ºC and 180 rpm. OD<sub>600</sub> measurements were done every half an hour, and 1 of each triplicates was induced at time 2.5 hours. All strains grew at the same pace and induction didn’t impair growth rate <b>(Fig. | + | <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088013">pSB1C3-Pcon-lacI:LVA-Plac-dxs <span class="specialWord">(B. subtilis)</span></a> were started from ONC at time 0 hours, OD<sub>600</sub>=0.005, and grown at 37ºC and 180 rpm. OD<sub>600</sub> measurements were done every half an hour, and 1 of each triplicates was induced at time 2.5 hours. All strains grew at the same pace and induction didn’t impair growth rate <b>(Fig. 2)</b>. |
</p> | </p> | ||
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<div class="imageGallery galleryMedium alignCenter"> | <div class="imageGallery galleryMedium alignCenter"> | ||
- | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/1/1b/SDU2013_Characterization_NMR_1.png" title="Figure | + | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/1/1b/SDU2013_Characterization_NMR_1.png" title="Figure 3 - Spectrum illustrating the pure polyisoprene standard (Mw = 38 kDa) H NMR spectrum. The peaks at 5.12, 2.04 and 1.68 indicates the (A), (B) and (C) protons of the isoprene monomer respectively. This sample was not dried in vacuum oven, and therefore we have a large peak at aprox. 1.55 corresponding to water."> |
- | <img src="https://static.igem.org/mediawiki/2013/1/1b/SDU2013_Characterization_NMR_1.png">Fig. | + | <img src="https://static.igem.org/mediawiki/2013/1/1b/SDU2013_Characterization_NMR_1.png">Fig. 3</a> |
- | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/f/f3/SDU2013_Characterization_NMR_2.png" title="Figure | + | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/f/f3/SDU2013_Characterization_NMR_2.png" title="Figure 4 - Spectrum illustrating the WT + polyisoprene standard, rubber purified, H NMR spectrum. The peaks at 5.12, 2.04 and 1.68 indicates the (A), (B) and (C) protons of the isoprene monomer respectively in this spectrum as well as the aforementioned pure polyisoprene H NMR spectrum. The different solvents of the rubber purification procedure is seen as well, however these are not interfering with out isoprene proton shifts."> |
- | <img src="https://static.igem.org/mediawiki/2013/f/f3/SDU2013_Characterization_NMR_2.png">Fig. | + | <img src="https://static.igem.org/mediawiki/2013/f/f3/SDU2013_Characterization_NMR_2.png">Fig. 4</a> |
- | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/0/04/SDU2013_Characterization_NMR_3.png" title="Figure | + | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/0/04/SDU2013_Characterization_NMR_3.png" title="Figure 5 - Spectrum illustrating our PT+DXS part. In this spectrum it is important to notice the same peaks as before, 5.12, 2.04, and 1.68 which reveals the presence of our polyisoprene. The same solvents as the previous spectrum is present, but the focus should be put towards the isoprene presence, proving the effect of HRT2/PT."> |
- | <img src="https://static.igem.org/mediawiki/2013/0/04/SDU2013_Characterization_NMR_3.png">Fig. | + | <img src="https://static.igem.org/mediawiki/2013/0/04/SDU2013_Characterization_NMR_3.png">Fig. 5</a> |
. | . | ||
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<p> | <p> | ||
- | Figure | + | Figure 3 illustrates the peaks given by pure polyisoprene are found at 5.12 (A), 2.04(B) and 1.68(C)in the ratio 1(A):4(B):3(C). Additionally, a peak is visible at 1.56 indicating water (the standard was not dried in a vacuum oven ON like the rubber extraction was). The peak at 0.00 ppm is the defining peak of the ppm axis and represents <span class="tooltipLink">TMS</span><span class="tooltip"><span class="tooltipHeader">TMS</span>Tetramethylsilane</span> which is a calibrating standard. |
</p> | </p> | ||
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<p> | <p> | ||
- | <span class="intro">The conclusion arrives in figure | + | <span class="intro">The conclusion arrives in figure 5</span>, named DXS+PT, which is our double plasmid CPS bacteria, and displays the same peaks (A), (B) and (C) as both the WT + polyisoprene and pure polyisoprene. This is a strong indication of the presence of rubber - specifically, this is an indication that our CPS bacteria produces rubber: Bacteriorganic Rubber. Peak distortion of the spectrum due to solvents are the same as seen in the rubber purification from WT + polyisoprene. |
</p> | </p> | ||
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<div class="imageGallery gallerySmall alignRight"> | <div class="imageGallery gallerySmall alignRight"> | ||
- | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/0/06/SDU2013_Characterization_NMR_4.png" title="Figure | + | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/0/06/SDU2013_Characterization_NMR_4.png" title="Figure 6 - Spectrum illustrating WT bacteria, which have undergone rubber purification. Notice that none of the peaks for the isoprene units are present in this spectrum. However it should be noticed that the vacuum oven was malfunctioning, and therefore this result might be due to insensitivity of the spectrometer, since the noise from the solvents are far greater than before."> |
- | <img src="https://static.igem.org/mediawiki/2013/0/06/SDU2013_Characterization_NMR_4.png">Fig. | + | <img src="https://static.igem.org/mediawiki/2013/0/06/SDU2013_Characterization_NMR_4.png">Fig. 6</a> |
- | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/9/9a/SDU2013_Characterization_NMR_5.png" title="Figure | + | <a class="galleryImg" target="_blank" href="https://static.igem.org/mediawiki/2013/9/9a/SDU2013_Characterization_NMR_5.png" title="Figure 7 - Spectrum illustrating PT+DXS, which have undergone rubber purification. The peak at 5.12 is vaguely present, and the rest of the peaks assigned to isoprene are hidden in the noise from the solvent and impurities. The peak at 5.12 is a triplet that corresponds to the previously observed shape of the 5.12 peak, and we expect that it is a indicator of the presence of polyisoprene production."> |
- | <img src="https://static.igem.org/mediawiki/2013/9/9a/SDU2013_Characterization_NMR_5.png">Fig. | + | <img src="https://static.igem.org/mediawiki/2013/9/9a/SDU2013_Characterization_NMR_5.png">Fig. 7</a> |
</div> | </div> | ||
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<p> | <p> | ||
- | The test provided the following results: Fig | + | The test provided the following results: Fig 6 lacks the characteristic peaks of polyisoprene at 5.12, 2.04 and 1.68. It can be concluded from their absence that there is not rubber (nor any other compound that might provide a similar chemical shift values) in the wildtype. In the CPS (fig. 7), we observe very a slight peak at 5.12, indicating the presence of (A) hydrogen. This peak has the same splitting pattern as the first round of H<sup>1</sup>-NMR, but it has a very low intensity. The (B) and (C) peaks are hidden in the background noise, which is most likely due to cell debris and solvents, which did not evaporate appropriately. We suspect that the machinery has a decreased sensitivity towards the isoprene peaks due to the high amount of solvent seen from the assigned peaks, but the peak at 5.12 (with the recognizable splitting pattern) is a strong indication that rubber is once again present in our CPS bacteria (containing both PT and dxs plasmids). |
</p> | </p> | ||
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Carrying the HRT2, <span class="specialWord">dxs</span> and both (CPS) devices and expressing the genes could impair the growth, and hence be important in production purpose. To test if the growth of MG1655 bacteria is impaired when carrying and expressing our devices, we measured the growth rate with OD<sub>600</sub> measurements. | Carrying the HRT2, <span class="specialWord">dxs</span> and both (CPS) devices and expressing the genes could impair the growth, and hence be important in production purpose. To test if the growth of MG1655 bacteria is impaired when carrying and expressing our devices, we measured the growth rate with OD<sub>600</sub> measurements. | ||
</p><p> | </p><p> | ||
- | Four different MG1655 strains carrying either no plasmid (WT), <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088016" title="">pSB1C3-Pcon-araC-term-Para-HRT2</a> (HRT2), <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088024" title="">pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis)</a> (Dxs), or pSB1K3-Pcon-araC-term-Para-HRT2 and pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis) (CPS), were grown from OD<sub>600</sub>=0.05 and induced with 1 mM IPTG and/or 0.2% arabinose during growth. The first experiment showed impaired growth of the bacteria only carrying construct expressing HRT2. We thought that the reason why the strains expressing HRT2 as well as Dxs didn’t show impaired growth rate could be due to a phenomenon called inclusion bodies. When overexpressing too many proteins, there is a risk of misfolding and hence loss of function. A way to lower this risk is to lower the temperature. Therefore we set up a growth experiment where the temperature was lowered from 37 to 20ºC at time of induction. This did not prove to make a difference, and CPS strains with and without IPTG and/or arabinose induction grew at same pace as WT <b>(fig | + | Four different MG1655 strains carrying either no plasmid (WT), <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088016" title="">pSB1C3-Pcon-araC-term-Para-HRT2</a> (HRT2), <a class="dialogLink" href="http://parts.igem.org/Part:BBa_K1088024" title="">pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis)</a> (Dxs), or pSB1K3-Pcon-araC-term-Para-HRT2 and pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis) (CPS), were grown from OD<sub>600</sub>=0.05 and induced with 1 mM IPTG and/or 0.2% arabinose during growth. The first experiment showed impaired growth of the bacteria only carrying construct expressing HRT2. We thought that the reason why the strains expressing HRT2 as well as Dxs didn’t show impaired growth rate could be due to a phenomenon called inclusion bodies. When overexpressing too many proteins, there is a risk of misfolding and hence loss of function. A way to lower this risk is to lower the temperature. Therefore we set up a growth experiment where the temperature was lowered from 37 to 20ºC at time of induction. This did not prove to make a difference, and CPS strains with and without IPTG and/or arabinose induction grew at same pace as WT <b>(fig 8)</b> |
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<a class="popupImg alignCenter" style="width:800px" href="https://static.igem.org/mediawiki/2013/6/64/SDU2013_Characterization_CPS_1.png" | <a class="popupImg alignCenter" style="width:800px" href="https://static.igem.org/mediawiki/2013/6/64/SDU2013_Characterization_CPS_1.png" | ||
- | title="Figure | + | title="Figure 8 - Growth experiments of MG1655 strains carrying either no plasmid (WT), pSB1C3-Pcon-araC-term-Para-HRT2 (BBa_1088016; HRT2), pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis) (BBa_1088024; Dxs), or pSB1K3-Pcon-araC-term-Para-HRT2 and pSB1C3-Pcon-lacI(N)-term-Plac-dxs (B. subtilis) (CPS). - and + indicates absence and presence, respectively of 1 mM IPTG and 0.2 % arabinose, respectively as well. The dashed line indicates time of induction with IPTG and/or arabinose. All strains were started at OD600=0.05 from an overnight culture, and were shaked with 180 rpm. A) The HRT2 strain grew slightly slower than the other strains at 37ºC, and upon induction some of the culture even seemed to die, though it catched up with the rest in the stationary phase. B) The CPS strain didn’t reflect what was seen in A when only the HRT2 expression was induced with arabinose. In this experiment WT grew slightly faster than CPS. C) WT and CPS was grown for 3 hours at 37ºC, and along with induction the temperature was lowered to 20ºC. This was done due to a hypothesis about a phenomenon called protein clouding (see main text for details). All strains grew at the same pace, in this experiment."> |
<img src="https://static.igem.org/mediawiki/2013/6/64/SDU2013_Characterization_CPS_1.png" | <img src="https://static.igem.org/mediawiki/2013/6/64/SDU2013_Characterization_CPS_1.png" | ||
style="width:800px"> | style="width:800px"> | ||
- | Figure | + | Figure 8 |
</a> | </a> | ||
Revision as of 19:20, 21 October 2013
Rubber results
Did we indeed make rubber?
Characterization of dxs (B. subtilis)
Functionality assayTo optimize the flow through the MEP pathway, the dxs gene was overexpressed, the expectation being increased levels of IPP and DMAPP(see Specification). To examine if overexpression indeed resultats in an increase in substrate, we attempted to assay the levels of DMAPP using a headspace gas chromatography (GC)-technique.
DMAPP was hydrolyzed in acid to the volatile hydrocarbon gas isoprene. The gas was subsequently analyzed with headspace GC. A linear relationship between amount of detected isoprene and DMAPP concentration has previously been established. Source: Alison J. Fisher et. al; Nonradioactive Assay for Cellular Dimethyllyl Diphosphate We were capable of producing a standard curve by reacting DMAPP with acid for 2 min (instead of the 60 min specified in the previous study) (Fig. 1). At this time, we obtained optimal peak detection for standard solutions. We were, however, incapable of detecting isoprene, even in high concentrations of bacterial samples treated with acid. The test was expanded to include acid hydrolyzation for 2, 30, 60 or 90 min, yet we could not detect isoprene, and therefore not detect DMAPP.
Figure 1. Optimization of the procedure is needed before characterization of the dxs bricks can be completed using this approach. We suspect that the complexity of the bacterial samples is too high, and thus the reaction does not take place as fast as might be necessary for detection in our setup. Sonication of bacterial samples with and without addition of standard DMAPP, and subsequent measurements might shed some light on this hypothesis. However, it should be noted that the GC wasn’t fully functional during the test period, consequently leading to broader peaks and thus lowered the sensitivity of the instrument. On the 3rd of October, we received a mail from Professor Lars Porskjær Christensen, Department of Chemistry-, Bio- and Environmental Technology, University of Southern Denmark:
"...The GC has now been repaired and the sensitivity has been improved considerably. The GC-peaks should be very sharp now. This may be the reason that you have not observed any release of isoprene from your samples...MailTranslated from danish".
Unfortunately, with only 2 days left to wiki-freeze, there was no time for another round of testing.
Growth Experiment
Figure 2.
Carrying the dxs devices and expressing the gene could impair the growth, and hence be important in production purpose. To test if the growth of MG1655 bacteria is impaired when carrying and expressing our dxs devices, we measured the growth rate with OD600 measurements.
Two triplicates of MG1655 carrying no vector, empty pSB1C3 vector, pSB1C3-Plac-dxs (B. subtilis), pSB1C3-Pcon-lacI-Plac-dxs (B. subtilis), or pSB1C3-Pcon-lacI:LVA-Plac-dxs (B. subtilis) were started from ONC at time 0 hours, OD600=0.005, and grown at 37ºC and 180 rpm. OD600 measurements were done every half an hour, and 1 of each triplicates was induced at time 2.5 hours. All strains grew at the same pace and induction didn’t impair growth rate (Fig. 2).
Characterization of HRT2
Rubber purificationTo discover rubber, it is useful to isolate the rubber from the rest of the bacterial cells. This will allow us to remove as many variables in the detection assays as possible. The rubber was purified according to self-written SOP0031 - Rubber purification. The method of purification was based on a literature search and chemical evaluation of solubility of the polyisoprene. Cells were sonicated in ethanol suspension, washed in acetone, and extracted in n-hexane (both steps were overnight).
Two different methods were tested to evaluate the most efficient extraction method. In the first method, we washed with acetone and extract with n-hexane in a soxhlet extractor. The second method excluded the time-consuming soxhlet steps and washed with acetone for a shorter duration of time (15 min shake at 37 deg). Rubber was extracted by adding hexane to the cell suspension, then centrifuging the sample. The supernatent was saved (hexane solution). We tested the methods of rubber extraction on a positive control made from MG1655, mixed with polyisoprene. Both the soxhlet and the non-soxhlet method were evaluated using H1-NMR. We deemed the results to be similar, and since the required time for non-soxhlet extraction was significantly less, we chose to use the non-soxleth method.
The H1 NMR test
We now seemed able to detect rubber that was extracted from a mixture of bacterial debris and polyisoprene, and felt ready for a test of our production system. H1 NMR allowed us a certain specificity and although a significant amount of polyisoprene was needed to enable detection, it was preferred over C13NMR. All samples were run an a bruker 400 mHz NMR spectrometer. We also knew that we could control the expression of the genes in both of our plasmids. We were ready to put our abilities to extract rubber through the non-soxhlet method and detect it using H1 NMR to the test. In other words, we were ready to find the rubber present in our strain! During the first test of our CPS bacteria (MG1655 transformed with both plasmids - see Design), bacteria were grown to late exponential phase at 37 deg, then induced with 1mM IPTG, 0.2% Ara, and 1mM MgCl2. It was then moved to room temperature for a further 4 hours of growth. Non-soxhlet extraction was used to purify any rubber present in the sample, which was then compared to a positive control (WT mixed with polyisopren - also undergone non-soxhlet extraction) and a standard isoprene solution.
Figure 3 illustrates the peaks given by pure polyisoprene are found at 5.12 (A), 2.04(B) and 1.68(C)in the ratio 1(A):4(B):3(C). Additionally, a peak is visible at 1.56 indicating water (the standard was not dried in a vacuum oven ON like the rubber extraction was). The peak at 0.00 ppm is the defining peak of the ppm axis and represents TMSTMSTetramethylsilane which is a calibrating standard.
Our rubber extraction of WT + polyisoprene gives the same peak placement as the pure polyisoprene ((A), (B) and (C)). However, the integration of the 3 peaks shows a relationship of approximately 1:5:4. The discrepancy can be explained by the impurities in the area between 0-2.5 ppm. Such impurities might add additional integration value to the peaks assigned to the polyisoprene peaks (B) and (C) - hereby causing a disruption of the true relationship. Some peaks from the solvents used to purify the rubber (Acetone, Ethanol, and Hexane), as well as a small amount of water (1.56 ppm) are seen, too.
The conclusion arrives in figure 5, named DXS+PT, which is our double plasmid CPS bacteria, and displays the same peaks (A), (B) and (C) as both the WT + polyisoprene and pure polyisoprene. This is a strong indication of the presence of rubber - specifically, this is an indication that our CPS bacteria produces rubber: Bacteriorganic Rubber. Peak distortion of the spectrum due to solvents are the same as seen in the rubber purification from WT + polyisoprene.
A second round of testing was done to validate the first experiment. We wanted to include a negative test (WT), in order to exclude the possibility of a naturally occurring polyisoprenoid compounds in E. coli. We performed rubber purification on WT, our CPS bacteria as well as a strain containing only the pSB1K3-AraC-Para-PT device. Bacteria were grown and rubber extracted as described above. The three samples where unfortunately not dried properly in the vacuum oven due to apparatus malfunction.
The test provided the following results: Fig 6 lacks the characteristic peaks of polyisoprene at 5.12, 2.04 and 1.68. It can be concluded from their absence that there is not rubber (nor any other compound that might provide a similar chemical shift values) in the wildtype. In the CPS (fig. 7), we observe very a slight peak at 5.12, indicating the presence of (A) hydrogen. This peak has the same splitting pattern as the first round of H1-NMR, but it has a very low intensity. The (B) and (C) peaks are hidden in the background noise, which is most likely due to cell debris and solvents, which did not evaporate appropriately. We suspect that the machinery has a decreased sensitivity towards the isoprene peaks due to the high amount of solvent seen from the assigned peaks, but the peak at 5.12 (with the recognizable splitting pattern) is a strong indication that rubber is once again present in our CPS bacteria (containing both PT and dxs plasmids).
The future of our H1 NMR test rubber characterization experiments will see us replicate our results. Specifically, we must redo the second rubber extraction and rerun the H1 NMR to verify the rubber presence in our CPS bacteria. Also, this particular rerun allows us to check that the WT is indeed lacking any sign of a peak at 5.12. In addition, we must investigate the rubber yield in terms of weight to further evaluate the two purification methods mentioned above.
MALDI-ToF
We thoroughly studied the literature concerning polyisoprene on MALDI-ToF and found that the formation of adducts by adding AgNO3- would make it possible to ionize the long alkene chain, despite its lack of functional groups that can be ionized.
We tried several matrixes including MBTMBT2-mercaptobenzothiazole, DHBDHB2,5-dihydroxybenzoic acid, CHCACHCAalpha-cyano-4-hydroxycinnamic acid, SASAsinapinic acid and DTDTdithranol, but didn't have the time to perform the tests on anything but our standard polyisoprene (Mw 38 kDa). Unfortunately, it appeared to be too large a molecule to be detected by the bruker MALDI-ToF machine. It was concluded that the machine's hardware settings could not match the requirements for such large molecules. However, the expected length that we expect HRT2 produces is in the 2-10 kDa range. This is within the limits of the machine, though we have yet to test this hypothesis as the machine is frequently occupied by other research groups.
Composite production system
Growth experimentsCarrying the HRT2, dxs and both (CPS) devices and expressing the genes could impair the growth, and hence be important in production purpose. To test if the growth of MG1655 bacteria is impaired when carrying and expressing our devices, we measured the growth rate with OD600 measurements.
Four different MG1655 strains carrying either no plasmid (WT), pSB1C3-Pcon-araC-term-Para-HRT2 (HRT2), pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis) (Dxs), or pSB1K3-Pcon-araC-term-Para-HRT2 and pSB1C3-Pcon-lacI(N)-term-Plac-dxs(B.subtilis) (CPS), were grown from OD600=0.05 and induced with 1 mM IPTG and/or 0.2% arabinose during growth. The first experiment showed impaired growth of the bacteria only carrying construct expressing HRT2. We thought that the reason why the strains expressing HRT2 as well as Dxs didn’t show impaired growth rate could be due to a phenomenon called inclusion bodies. When overexpressing too many proteins, there is a risk of misfolding and hence loss of function. A way to lower this risk is to lower the temperature. Therefore we set up a growth experiment where the temperature was lowered from 37 to 20ºC at time of induction. This did not prove to make a difference, and CPS strains with and without IPTG and/or arabinose induction grew at same pace as WT (fig 8)