Difference between revisions of "Team:SDU-CHINA/Results"

 
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<h1 id="main-title">Results</h1>
 
<h1 id="main-title">Results</h1>
 
<h4 id="main-title">Attempt to build the split RNAP</h4>
 
<h4 id="main-title">Attempt to build the split RNAP</h4>
<p>We initially chose a blue-light-controlled sensor as candidate. The sensor, opto-T7RNAP is a pair of fusion proteins which initiates transcription of PT7 by dimerize when exposed to light 450nm. nMag is fused with the CT (carbon terminal) of T7RNAP and pMag is fused with NT (nitrogen terminal). Due to the toxicity of the part, the expression of both the two fusion proteins are induced by arabinose. And we set a concentration gradient to explore the optimized condition.</p>
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<p>We initially chose a blue-light-controlled sensor as candidate. The sensor, opto T7 RNA polymerase  is a pair of fusion proteins which initiates transcription of P<sub>T7</sub> by dimerize when exposed to light 450 nm. nMag is fused with the CT (carbon terminal)<sup>[1]</sup> of T7RNAP and pMag is fused with NT (nitrogen terminal). Due to the toxicity of the part, the expression of both the two fusion proteins are induced by L-arabinose<sup>[2]</sup>. And we set a concentration gradient to explore the optimized condition.</p>
<p>We inserted the sfGFP after the PT7 to characterize the behavior of the blue light sensor. The experimental result shows no significant induction compared with the dark control.</p>
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<h4>1. Characterization of sensor opto T7 RNAP</h4>
<img src="https://static.igem.org/mediawiki/2018/0/09/T--SDU-CHINA--result1.png" width="400"><br>
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<p>We inserted the sfGFP after the P<sub>T7</sub> to characterize the behavior of the blue light sensor. The experimental result shows no significant induction compared with the dark control.</p>
<img src="https://static.igem.org/mediawiki/2018/e/e3/T--SDU-CHINA--result2.png" width="800">
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<img src="https://static.igem.org/mediawiki/2018/e/e3/T--SDU-CHINA--result2.png" width="800" title="Figure 2. Dynamic experiment of the expression level of Opto-T7RNAP. The sensor is exposed to blue light and dark respectively at 0h. Result showed no significant expression of sfGFP." alt="Figure 1. Dynamic experiment of the expression level of Opto-T7RNAP. The sensor is exposed to blue light and dark respectively at 0h. Result showed no significant expression of sfGFP.">
<p>Thus, we decided to verify the expression level of nMag and pMag. To verify the expression of the sensors, whose MWs are 53.9kD and 78.5kD respectively. We tested the sample containing sensor induced by 0, 0.1%, 0.2%, 0.5% arabinose and empty vector.</p>
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<div style="text-align: center; font-size: 15px">Figure 1. Dynamic experiment of the expression level of Opto-T7RNAP. The sensor is exposed to blue light and dark respectively at 0h. Result showed no significant expression of sfGFP.</div>
<p>The SDS-PAGE result shows no significant existence of the sensors.</p>
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<img src="https://static.igem.org/mediawiki/2018/6/60/T--SDU-CHINA--result3.png" width="600">
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<p>The result above might be caused at the level of the transcription of sensors. For the future, we plan to change the backbone into a high-copied one to make the result more significant. And we intend to replace the araBAD promoter with a constitutive promoter to keep the sensor at a steady level.</p>
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<h4>2.Validation at protein level</h4>
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<p>To verify the expression of the sensors, whose MWs are 53.9kD and 78.5kD respectively. We tested the sample containing sensor induced by 0, 0.1%, 0.2%, 0.5% arabinose and empty vector. The SDS-PAGE result shows no significant existence of the sensors.</p>
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<img src="https://static.igem.org/mediawiki/2018/6/60/T--SDU-CHINA--result3.png" width="600" title="Figure 2. Analysis sensor expression in total E. coli protein by SDS PAGE." alt="Figure 2. Analysis sensor expression in total E. coli protein by SDS PAGE.">
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<div style="text-align: center; font-size: 15px">Figure 2. Analysis sensor expression in total E. coli protein by SDS PAGE.</div>
  
<h4 id="main-title">Characterization of CcaS-CcaR TCS system</h4>
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<h4 id="main-title">Characterization of CcaS/CcaR system</h4>
<p>The CcaS protein acts as a light sensing part in CcaS-CcaR two-component system (TCS). CcaS consists of an N-terminal transmembrane helix; a GAF domain, which serves as the sensor domain; a linker region (L1); two PAS domains; a second linker region (L2); and a C-terminal histidine kinase (HK) domain. We were inspired by Professor Koji’s work[1] to  remove the L1 linker region and the two PAS domains, then fuse the GAF and HK domains with a truncated linker region.</p>
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<p>The CcaS protein acts as a light sensing part in CcaS/CcaR two-component system (TCS). CcaS consists of an N-terminal transmembrane helix; a GAF domain, which serves as the sensor domain; a linker region (L1); two PAS domains; a second linker region (L2); and a C-terminal histidine kinase (HK) domain. We were inspired by Professor Koji’s work<sup>[3]</sup> to  remove the L1 linker region and the two PAS domains, then fuse the GAF and HK domains with a truncated linker region.</p>
<img src="https://static.igem.org/mediawiki/2018/d/d1/T--SDU-CHINA--result4.png" width="800">
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<img src="https://static.igem.org/mediawiki/2018/d/d1/T--SDU-CHINA--result4.png" width="800" title="Figure 3. Domain organization of wild-type CcaS and miniaturized CcaSs." alt="Figure 3. Domain organization of wild-type CcaS and miniaturized CcaSs.">
<p>Our advanced system was characterized over wild type in M9 medium. The fluorescence intensity was acquired 9 hours after inoculated into 24-well plate with Abs600 about 0.1. Our culture was exposed to different light to characterize different transcription level. The basic OD and fluorescence were wiped off. (n=3)</p>
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<div style="text-align: center; font-size: 15px">Figure 3. Domain organization of wild-type CcaS and miniaturized CcaSs.</div><br>
<img src="https://static.igem.org/mediawiki/2018/e/e6/T--SDU-CHINA--result5.png" width="600">
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<p>The dynamic ranges of green over red light of different system are: 2.8(Wild type), 2.7(#3), 4.9(#10). The #4 has the reverse function and the dynamic range is about 1.5.</p>
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<p>Our advanced system was characterized over wild type in M9 medium containing 2% glucose but without yeast extract. The fluorescence intensity was acquired 9 hours after inoculated into 24-well plate with Abs600 about 0.1. Our culture was exposed to different light to characterize different transcription level. The basic OD and fluorescence were wiped off. (n=3)</p>
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<img src="https://static.igem.org/mediawiki/2018/e/e6/T--SDU-CHINA--result5.png" width="600" title="Figure 4. This figure shows the fluorescence of cells grown under green light (green bars), red light (red bars), and darkness (gray). Bars indicate relative fluorescence intensity to normalized fluorescence level of wild type. Data represent means ±SD from three repeat experiment (n=3)." alt="Figure 4. This figure shows the fluorescence of cells grown under green light (green bars), red light (red bars), and darkness (gray). Bars indicate relative fluorescence intensity to normalized fluorescence level of wild type. Data represent means ±SD from three repeat experiment (n=3).">
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<div style="text-align: center; font-size: 15px">Figure 4. This figure shows the fluorescence of cells grown under green light (green bars), red light (red bars). Bars indicate relative fluorescence intensity to normalized fluorescence level of wild type. Data represent means ±SD from three repeat experiment (n=3).</div><br>
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<p>The dynamic ranges of green over red light of different system are: 2.8(wild type), 2.7(#3), 4.9(#10). The #4 has the reverse function and the dynamic range is about 1.5.</p>
  
  
 
<h4 id="main-title">The construction of the metabolic flux regulation platform.</h4>
 
<h4 id="main-title">The construction of the metabolic flux regulation platform.</h4>
<p>We selected type-I-E CRISPR system as the cutover dynamically switching the metabolic flux. Type-I-E CRISPR system can inhibit the aimed gene’s transcription through expressing crRNA combining endogenous Cas protein.</p>
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<p>We selected type I-E CRISPRi system as the cut-over dynamically switching the metabolic flux. Type I-E CRISPRi system can inhibit the aimed gene’s transcription through expressing crRNA combining endogenous Cas protein.</p>
<div>1. Characterization of type-I-E CRISPR system</div>
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<h4>1. Characterization of type I-E CRISPRi system</h4>
<p>To remove the DNA degradation function and maintain the DNA binding function of the modified type I-E CRISPR system, a special E.coli TOP10 with Cas3 protein knocked out and promoter of Cascade substituted by promoter J23119 was constructed and named EE-E15. To verify the system in EE-E15, the GFP gene was chosen as a reporter to test the function of crRNA targeting different sites of GFP. The results showed that there were wide rages of repression among different sites and the spacer posited on the promotor region presented high repression level (82%).</p>
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<p>To remove the DNA degradation function and maintain the DNA binding function of the modified type I-E CRISPR system, a special <i>E.coli</i> TOP10 with Cas3 protein knocked out and promoter of Cascade substituted by promoter J23119 was constructed and named EE-E15. To verify the system in EE-E15, the GFP gene was chosen as a reporter to test the function of crRNA targeting different sites of GFP<i>[4]</i>. The results showed that there were wide rages of repression among different sites and the spacer posited on the promotor region presented high repression level (82%).</p>
<img src="https://static.igem.org/mediawiki/2018/2/20/T--SDU-CHINA--result6.png" width="600">
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<img src="https://static.igem.org/mediawiki/2018/2/20/T--SDU-CHINA--result6.png" width="800" title="Figure 5. The site of spacers target gfp." alt="Figure 5. The site of spacers target gfp.">
<p>TCA cycle is one of the most significant metabolic pathways for energy supplement. The cycle starts with the process that citrate synthase catalyzes acetyl-coA and oxaloacetate to form citric, which is the rate-limiting step in the TCA cycle and irreversible, thus the regulation of expression of gltA which codes the citrate synthase may have great effect in central metabolism, and through model we also found that control of gltA can regulate the metabolic flux. We got the target site of gltA gene from previous work and then we constructed a plasmid containing crRNA targeting gltA to inhibit expression. With 0.2% L-arabinose induction, the samples showed an obvious repression on growth compared with the ones without L-arabinose (figure 2.). furthermore, we investigated the regulatory effects of targeting gltA at different stages of growth by adding L-arabinose at 0h, 2.5h, 5h, 7.5h and 9h. As shown in the figure, there presented an obvious difference between different induced time, in which the strains added L-arabinose at the beginning had the strongest repression in growth while with the delay of the induction time, the effect of inhibiting growth was gradually weakened. It indicated that this system can inhibit TCA cycle through inducing crRNA targeting gltA at different time, thus it proved that our idea that dynamically regulating metabolic flux was feasible to some extent.</p>
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<div style="text-align: center; font-size: 15px">Figure 5. The site of spacers target gfp.</div>
<img src="https://static.igem.org/mediawiki/2018/3/3e/T--SDU-CHINA--result7.png" width="1000"><br>
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<img src="https://static.igem.org/mediawiki/2018/4/46/T--SDU-CHINA--result8.png" width="1000"><br>
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<img src="https://static.igem.org/mediawiki/2018/3/3e/T--SDU-CHINA--result7.png" width="850" title="Figure 6. Characterization of type I-E CRISPRi system targeting different sites of gfp." alt="Figure 6. Characterization of type I-E CRISPRi system targeting different sites of gfp.">
<img src="https://static.igem.org/mediawiki/2018/c/ca/T--SDU-CHINA--result9.png" width="1000">
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<div style="text-align: center; font-size: 15px">Figure 6. Characterization of type I-E CRISPRi system targeting different sites of gfp.</div><br>
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<p>TCA cycle is one of the most significant metabolic pathways for energy supplement. The cycle starts with the process that citrate synthase catalyzes acetyl-coA and oxaloacetate to form citric, which is the rate-limiting step in the TCA cycle and irreversible, thus the regulation of expression of <i>gltA</i> which codes the citrate synthase may have great effect in central metabolism, and through model we also found that control of <i>gltA</i> can regulate the metabolic flux. We got the target site of <i>gltA</i> gene from previous work and then constructed a medium-copy plasmid (Paracr15A) and a high-copy plasmid (Paracr58.6) containing crRNA targeting <i>gltA</i>  to inhibit expression. With 0.2% L-arabinose induction, the samples showed an obvious repression on growth compared with those without L-arabinose, regardless of the copy number difference between Paracr15A and Paracr58.6(Figure 8). Among them, aracr58.6 grew slower, which may due to its high leakage with high-copy plasmids. It indicated that this Type-I-E CRISPRi system can affect cell growth through producing crRNA targeting  <i>gltA</i>.</p>
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<img src="https://static.igem.org/mediawiki/2018/4/46/T--SDU-CHINA--result8.png" width="750" title="Figure 7. The posited site of crRNA targeting gltA to inhibit it’s transcription." alt="Figure 7. The posited site of crRNA targeting gltA to inhibit it’s transcription.">
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<div style="text-align: center; font-size: 15px">Figure 7. The posited site of crRNA targeting <i>gltA</i> to inhibit it’s transcription.</div><br>
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<img src="https://static.igem.org/mediawiki/2018/f/fe/T--SDU-CHINA--arabinosechanged.png" width="800" title="Figure 8. Regulation effect of crRNA induced by L-arabinose between medium-copy and high-copy plasmids. The strains were cultured in 24-well plate in 1 ml M9 medium containing 1% glycerol." alt="Figure 8. Regulation effect of crRNA induced by L-arabinose between medium-copy and high-copy plasmids. The strains were cultured in 24-well plate in 1 ml M9 medium containing 1% glycerol.">
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<div style="text-align: center; font-size: 15px">Figure 8. Regulation effect of crRNA induced by L-arabinose between medium-copy and high-copy plasmids. The strains were cultured in 24-well plate in 1 ml M9 medium containing 1% glycerol.</div>
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<h4>2. light-induced type I-E CRISPRi system</h4>
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<p>Further, we utilized CcaS/CcaR sensor with type I-E CRISPRi system to induction of crRNA targeting the site of <i>gltA</i> through switching light. To optimize this system, we chose different culture medium verifying the function of light-induced crRNA.</p>
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<img src="https://static.igem.org/mediawiki/2018/7/7d/T--SDU-CHINA--result10.png" width="500" title="Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates." alt="Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates." height="350">
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<img src="https://static.igem.org/mediawiki/2018/d/da/T--SDU-CHINA--result11.png" width="500" title="Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates." alt="Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates." height="350">
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<div style="text-align: center; font-size: 15px">Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates.</div><br>
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<p>In the figures we can find that cell cultured with glycerol growth had a higher level of repression compared with glucose. It indicates that crRNA targeting  <i>gltA</i> to inhibit TCA cycle from the first step showed a better effect when nutrition was not directly utilized. In addition, it illustrates that condition made sense for the function of our system. Meanwhile the phenomenon was analyzed through <a href="https://2018.igem.org/Team:SDU-CHINA/Model">flux balance analysis (FBA) mathematical model</a>. With the data we found there was a threshold when inhibiting  <i>gltA</i>, exceeding which appears an obvious transform in metabolic flux. We analyzed that glycerol as carbon source can reduce this threshold showing great repression which was in accordance with the growth results described above. Then we chose M9 medium with 1% glycerol as the condition for the characterization of crRNA targeting <i>gltA</i>.</p>
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<p>To optimize the expression of crRNAs in EE-E15, then we constructed a medium-copy plasmid (pSR43.6) and high-copy plasmid (phz) to express crRNA targeting endogenous <i>gltA</i>. The two strains showed significant variance in growth in figure 4, suggesting crRNA on high-copy plasmid showed stronger repression than on medium-copy one. We supposed that the inhibition function was related to the quantity of crRNA and light-sensing promotor PcpG2-172 works well in high-copy number, leading to this result. It indicated that copy-number for light-induced crRNA had a great impact on this photoactivated regulation system.</p>
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<img src="https://static.igem.org/mediawiki/2018/f/fe/T--SDU-CHINA--result12.png" width="800" title="Figure 10. Comparison of the regulatory effect between medium-copy and high-copy plasmids. #10 43.6 is a medium-copy plasmid (p15A ori) expressing crRNA while high-copy for #10 phz (CoIE1). The strains were cultured in 24-well plate in 1ml M9 medium containing 1% glycerol." alt="Figure 10. Comparison of the regulatory effect between medium-copy and high-copy plasmids. #10 43.6 is a medium-copy plasmid (p15A ori) expressing crRNA while high-copy for #10 phz (CoIE1). The strains were cultured in 24-well plate in 1ml M9 medium containing 1% glycerol.">
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<div style="text-align: center; font-size: 15px">Figure 10. Comparison of the regulatory effect between medium-copy and high-copy plasmids. #10 43.6 is a medium-copy plasmid (p15A ori) expressing crRNA while high-copy for #10 phz (CoIE1). The strains were cultured in 24-well plate in 1ml M9 medium containing 1% glycerol.</div><br>
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<p>After the verification of the culture condition, we investigated the dynamic regulation effects of targeting <i>gltA</i> with light-controlled system through switching red light to green light at 2h, 5h and 9h. As shown in figure 5, all strains induced at different time grow better compared with illuminating at 0h. Bacteria growth was inhibited the most when being induced at 5h, showing an obvious palliation after sensing green light. The strains induced at the early-log phase (2h) grew slower than the control (upon red illumination), whereas it continuously grew and maintained a relatively high K value. It was supposed that cells growing at a moderate speed at early consumed less nutrition, thus drove the biomass constantly increase and had a higher level of K value. In accordance with the hypothesis, we concluded the negative control without crRNA targeting <i>gltA</i> which presented a lowest level of K value consumed too much nutrition so that it can’t satisfy the need of cell in late period of growth. In addition, inducing crRNA expression at 9h through green light, we found there were little growth variance between the strains green light induced at 9h and the control illuminated at red light continuously. It was supposed that at the stationary phase there was nearly no effect for inhibiting TCA cycle to repress the cell’s growth, which might due to its metabolic flow. The difference between the regulation effect of different induction time isn’t obvious through light switching, might due to light sensor CcaS/CcaR system which only have 4.8-fold difference between red/green light induction.</p>
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<img src="https://static.igem.org/mediawiki/2018/c/c4/T--SDU-CHINA--result13.png" width="800" tile="Figure 11. Regulation effect of crRNA induced at different time by switching to green light. The strains were cultured in 50ml M9 medium containing 1% glycerol." alt="Figure 11. Regulation effect of crRNA induced at different time by switching to green light. The strains were cultured in 50ml M9 medium containing 1% glycerol.">
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<div style="text-align: center; font-size: 15px">Figure 11. Regulation effect of crRNA induced at different time by switching to green light. The strains were cultured in 50ml M9 medium containing 1% glycerol.</div><br>
  
<div>2. light-induced type-I-E CRISPR system</div>
 
<p>Further, we utilized CcaS/CcaR sensor with type-I-E CRISPR system to induction of crRNA targeting the site of gltA through switching light. To optimize this system, we chose different culture medium verifying the function of light-induced crRNA.</p>
 
<img src="https://static.igem.org/mediawiki/2018/7/7d/T--SDU-CHINA--result10.png" width="1000"><br>
 
<img src="https://static.igem.org/mediawiki/2018/d/da/T--SDU-CHINA--result11.png" width="1000">
 
<p>In the figures we can find that cell cultured with glycerol growth had a higher level of repression compared with glucose. It indicates that crRNA targeting gltA to inhibit TCA cycle from the first step showed a better effect when nutrition was not directly utilized. In addition, it illustrates that condition made sense for the function of our system. Meanwhile the phenomenon was analyzed through flux balance analysis (FBA) mathematical model. With the data we found there was a threshold when inhibiting gltA, exceeding which appears an obvious transform in metabolic flux. We analyzed that glycerol as carbon source can reduce this threshold showing great repression which was in accordance with the growth results described above. Then we chose M9 medium with 1% glycerol as the condition for the characterization of crRNA targeting gltA.</p>
 
<p>To optimize the expression of crRNAs in EE-E15, then we constructed a medium-copy plasmid (pSR43.6) and high-copy plasmid (phz) to express crRNA targeting endogenous gltA. The two strains showed significant variance in growth in figure 4, suggesting crRNA on high-copy plasmid showed stronger repression than on medium-copy one. We supposed that the inhibition function was related to the quantity of crRNA and light-sensing promotor PcpG2-172 works well in high-copy number, leading to this result. It indicated that copy-number for light-induced crRNA had a great impact on this photoactivated regulation system.</p>
 
<img src="https://static.igem.org/mediawiki/2018/f/fe/T--SDU-CHINA--result12.png" width="800">
 
<p>After the verification of the culture condition, we investigated the dynamic regulation effects of targeting gltA with light-controlled system through switching red light to green light at 2h, 5h and 9h. As shown in figure 5, all strains induced at different time grow better compared with illuminating at 0h. Bacteria growth was inhibited the most when being induced at 5h, showing an obvious palliation after sensing green light. The strains induced at the early-log phase (2h) grew slower than the control (upon red illumination), whereas it continuously grew and maintained a relatively high K value. It was supposed that cells growing at a moderate speed at early consumed less nutrition, thus drove the biomass constantly increase and had a higher level of K value. In accordance with the hypothesis, we concluded the negative control without crRNA targeting gltA which presented a lowest level of K value consumed too much nutrition so that it can’t satisfy the need of cell in late period of growth. In addition, inducing crRNA expression at 9h through green light, we found there were little growth variance between the strains green light induced at 9h and the control illuminated at red light continuously. It was supposed that at the stationary phase there was nearly no effect for inhibiting TCA cycle to repress the cell’s growth, which might due to its metabolic flow. The difference between the regulation effect of different induction time isn’t obvious through light switching compared with L-arabinose (figure 2.), might due to light sensor CcaS/CcaR system which only have 4.8-fold difference between red/green light induction.</p>
 
<img src="https://static.igem.org/mediawiki/2018/c/c4/T--SDU-CHINA--result13.png" width="800">
 
 
<p>We reconstructed EE-E15 driving its metabolic flux regulation at different time through switching red light to the green one. Then we made polyhydroxybutyrate(PHB) as an example to demonstrate our dynamically regulating metabolic flux platform.</p>
 
<p>We reconstructed EE-E15 driving its metabolic flux regulation at different time through switching red light to the green one. Then we made polyhydroxybutyrate(PHB) as an example to demonstrate our dynamically regulating metabolic flux platform.</p>
  
  
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<h4 id="main-title">PHB fermentation</h4><br>
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<h4>1. PHB synthesis with CcaS/CcaR system</h4>
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<p>Firstly, in order to verify that phbCAB cluster could be expressed induced by CcaS/CcaR system and synthesize Polyhydroxybutyrate (PHB) successfully, phbCAB cluster (without its original constitutive promoter) was cloned right behind the light sensing promoter, PcpcG2-172 (Figure 12).</p>
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<img src="https://static.igem.org/mediawiki/2018/a/a2/T--SDU-CHINA--result15.png" height="250" title="Figure 12. Gene circuit of PHB induced” alt="Figure 12. Gene circuit of PHB induced">
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<div style="text-align: center; font-size: 15px">Figure 12. Gene circuit of "PHB induced”</div><br>
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<p>Also strain “PHB induced Red/Green” was illuminated with red light and green light respectively throughout the PHB fermentation while light illuminating “PHB induced 5h” was switched from red light to green light at 5h (exponential phase) so that we can tell whether turning on PHB synthesis pathway at different periods could affect PHB content within the cells and cell growth, as well.</p>
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<img src="https://static.igem.org/mediawiki/2018/1/12/T--SDU-CHINA--result16.png" width="650"><br>
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<img src="https://static.igem.org/mediawiki/2018/4/4a/T--SDU-CHINA--result17.png" width="350"">
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<img src="https://static.igem.org/mediawiki/2018/c/cf/T--SDU-CHINA--result18.png" width="300">
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<div style="text-align: center; font-size: 15px">Figure 13.Cell growth curve and PHB production among strain “PHB induced”. In groups "PHB induced 5h/Green", the expression of phbCAB is activated at 0h and 5h respectively. In contrast "PHB induced Red" are illuminated by red light throughout the fermentation to inhibit the crRNA expression. (a) cell growth curve during the PHB fermentation. (b) the ratio between PHB and cell drought weight, showing the average PHB content within each cell. (c) total amount of PHB produced during the fermentation.</div><br>
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<p>According to the PHB fermentation results, CcaS/CcaR system expressed phbCAB cluster successfully (Figure 13.b c). What’s more, a large amount of PHB could be synthesized as PHB took up over 30% of cell drought at the end of fermentation in “PHB induced Green" (Figure 13.b). Furthermore, the amount of PHB inside the cells increased as the amount of time for phbCAB cluster expression increased, which was consistent with our expectation (Figure 13.b). However, to our surprise, it appeared that those groups containing higher PHB content tended to grow better than those with less PHB. After searching articles on the relationship between PHB synthesis and bacteria stress tolerance, we found out that the biosynthesized PHB stored inside the cell can serve as an intracellular energy and carbon storage system and thus, increases the cell survival rate when carbon source is limited.[5] This probably explains the reason why the “PHB induced” that synthesized more PHB tend to have higher cell density for the duration of fermentation. </p>
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<h4>2. Effect of metabolic flux redirection on PHB production<h4>
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<p>Since we have demonstrated that a great deal of PHB can be synthesized under the control of CcaS/CcaA system, we then hope to verify that the inhibition of <i>gltA</i> gene by crRNA as well as type I-E CRISPRi system can improve PHB production through metabolic flux redirection. Therefore, we constructed another <i>E. coli</i> strain, “PHB con+crRNA”, which expresses phbCAB constitutively with its original promoter within the operon and expresses crRNA through CcaS/CcaA system (Figure 14).</p>
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<img src="https://static.igem.org/mediawiki/2018/f/fd/T--SDU-CHINA--R1.png" width="700">
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<div style="text-align: center; font-size: 15px">Figure 14. Gene circuit of “PHB con+crRNA”</div><br>
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<p>Furthermore, the expression of crRNA was turned on at different periods of PHB fermentation. To be more specific, “PHB con+crRNA 5h/13.5h” expressed crRNA at 5h (exponential phase) and 13.5h (stationary phase) respectively by switching from red light illumination into green light. And besides, “PHB con+crRNA Red” was illuminated with red light all the time while “PHB con+crRNA Green” expressed crRNA throughout the fermentation (lag phase).</p>
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<img src="https://static.igem.org/mediawiki/2018/b/b5/T--SDU-CHINA--R2.png" width="650"><br>
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<img src="https://static.igem.org/mediawiki/2018/c/c9/T--SDU-CHINA--R3.png" width="350">
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<img src="https://static.igem.org/mediawiki/2018/c/c3/T--SDU-CHINA--R4.png" width="350">
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<div style="text-align: center; font-size: 15px">Figure 15. Cell growth curve and PHB production of strain “PHB con+crRNA”. In "PHB con+crRNA Green/5h/13.5h", the expression of crRNA is activated at the beginning (0h), 5h and 13.5h respectively. By contrast, "PHB con+crRNA Red" is incubated under red light all the time to suppress crRNA expression. (a) the cell growth curve during the PHB fermentation. (b) the ratio between PHB and cell drought weight. (c) total amount of PHB produced during the fermentation.</div><br>
 +
 +
<p>As we can see, despite “PHB con+crRNA Red” grew slightly better than the other, there was no significant difference between “PHB con+crRNA Green/5h/13.5h” (Figure 15. a), which meant that unlike the results shown on crRNA characterization, here, crRNA doesn’t inhibit cell grow. Based on the former PHB fermentation result, this was probably because the PHB synthesized by <i>E. coli</i> also has a positive effect on cell growth which offsets the detrimental impact of crRNA. And since crRNA was just expressed at a leaky level, “PHB con+crRNA Red” seems to grow slightly better than the other groups.</p>
  
<h4 id="main-title">PHB fermentation</h4>
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<p>With respect to PHB production, “PHB con+crRNA Red” with leaky expression of crRNA produced less PHB showing that the inhibition of <i>gltA</i> gene by crRNA improved PHB production dramatically (Figure 15. b c). And more importantly, the amount of PHB within the cells is different among different “PHB con+crRNA” group (Figure 15. b). That’s to say, the expressing crRNA at different periods of fermentation might lead to the variation of PHB content. In addition, “PHB con+crRNA 5h” tended to produce more PHB as shown in the data (Figure 15. b c) in comparison to “PHB con+crRNA Green/13.5h”. Thus, we can express crRNA at exponential phase to improve PHB production while turning on crRNA at stationary phase would be a bad choice.</p>
<p>Firstly, in order to illustrate the effect of crRNA on PHB production, phbCAD gene cluster was expressed constitutively by its original promoter, then gltA gene was inhibited by crRNA and type I-E CRISPRi system (Figure 1.a). And strain “phb con” with no crRNA (Figure 2.b) was the negative control.</p>
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<img src="https://static.igem.org/mediawiki/2018/0/00/T--SDU-CHINA--result14.png" height="300">
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<img src="https://static.igem.org/mediawiki/2018/a/a2/T--SDU-CHINA--result15.png" height="300">
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<p>The expression of crRNA was turned on by switching red light illumination into green light illumination at log phase(oh), exponential phase(5h) and stationary phase(13.5h) respectively to show whether crRNA would lead to the variation of PHB content within cells. If "phb con + crRNA” were inhibited by crRNA, but with high level of PHB production compared with those without crRNA, then we could tell that probably the inhibition of gltA by crRNA does improve PHB production. Furthermore, if PHB content inside the cells varied between "phb con + crRNA oh/5h/13.5h”in which gltA was knocked down at distant fermentation periods, we might draw the conclusion that our growth-production switching system would work successfully in the example of PHB fermentation. However, the fermentation result was not as what we expected it to be.</p>
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<img src="https://static.igem.org/mediawiki/2018/1/12/T--SDU-CHINA--result16.png" width="800"><br>
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<img src="https://static.igem.org/mediawiki/2018/4/4a/T--SDU-CHINA--result17.png" width="500"">
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<img src="https://static.igem.org/mediawiki/2018/c/cf/T--SDU-CHINA--result18.png" width="500">
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<p>Though green light is turned on at different fermentation periods, there is no distinguishable growing difference between "phb con + crRNA 0h/5h and 13.5h". And furthermore, a striking decrease on OD can be found among strains "phb con + crRNA" compared to negative control (“phb con”) (Figure 2.a). So it is considered that the expression of crRNA, even at a low leakage expressing level, has a significant detrimental impact on cell growth. However, cell growth is inhibited on almost the same level, in spite of high or low transcription level as no significant difference can be told among “phb con 0h/5h/13.5h/Red”. On the other hand, there is no distinguishable distinction of PHB content between "phb con + crRNA 0h/5h/13.5h" and "phb con", while "phb con + crRNA Red" produce only half as much PHB as the others (Figure 2.b). Hence, it seems that crRNA transcribed by CcaS/CcaA system under green light, cannot improve PHB content as we expected. And besides, surprisingly, the leaky expression of crRNA under red light decreases the PHB content inside the cells (Figure 2.b). This is probably because the impact of crRNA varies from different expression level. Combining the cell growth as well as the PHB production result discussed above, we can see clearly, "phb con" in fact produce more PHB than others (Figure 2.c).</p>
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<p>Despite of the experiment above, we conducted another experiment meanwhile. In order to demonstrate our growth-production switching system, here, both phaCAD cluster and crRNA is expressed under CcaS/CcaA system (Figure 3.a, b). However, the plasmid engaged here has a slight difference from the one used in the former experiment---crRNA is expressed on a low-copy-number plasmid. This is because we were running out of and thus didn’t construct the high-copy-number plasmid. And what's worse, the data of "phb induced + crRNA 13.5h" and "phb induced 13.5h" was lost by mistakes.</p>
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<img src="https://static.igem.org/mediawiki/2018/d/d6/T--SDU-CHINA--result19.png" height="300">
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<img src="https://static.igem.org/mediawiki/2018/3/38/T--SDU-CHINA--result20.png" height="300"><br>
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<img src="https://static.igem.org/mediawiki/2018/9/92/T--SDU-CHINA--result21.png" width="800"><br>
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<img src="https://static.igem.org/mediawiki/2018/5/56/T--SDU-CHINA--result22.png" width="500">
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<img src="https://static.igem.org/mediawiki/2018/5/5e/T--SDU-CHINA--result23.png" width="500">
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<p>Opposite to the first experiment, here we found out that the expression of crRNA actually contributes to the high cell density in "phb induced + crRNA 0h/5h" groups for the duration of PHB fermentation (Figure 4.a). This surprising result was completely to the opposite to our expectation, as crRNA was supposed to inhibit TCA pathway and thus, have a dramatically detrimental effect on cell growth. But to some extent, it was consistent to the part of the results of our former experiments. For the duration of crRNA characterization and PHB fermentation seed culturing, we did witness the tendency that in spite of being depressed by crRNA, E. coli will would grow slowly after entering the platform period and probably will grow better than the control in the long run (data not shown). With respect to PHB content, no significant difference could be told between "phb induced + crRNA 0h/5h" and "phb induced 0h/5h" (Figure 4.b), consistent to the first experiment. In addition, "phb induced + crRNA Red" containsed as much PHB content as "phb induced Red" (Figure 4.b). Thus, it appeared that crRNA expressed on low-copy-number plasmid had no impact on PHB production.</p>
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<p>According to the PHB fermentation data, the effect of crRNA on both cell growth and PHB production is very complicated. From these two experiments, it appears that the specific impact of crRNA on cell growth has something to do with the expression level, generally, significant decrease in OD can only be seen in those groups expressing crRNA on a high-copy-number plasmid while an increase in OD is witnessed in those groups expressing crRNA on a high-copy-number plasmid. In addition, though the expression of crRNA on low or high-copy-number plasmid does not improve PHB production, the leaky expression of crRNA on high-copy-number plasmid somehow can be detrimental to PHB biosynthesis. So our growth-production switching system failed in the example of PHB fermentation as crRNA has a complicated impact on cell growth and cannot improve PHB content as we expected.<p>
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<p>In short, expressing crRNA can improve PHB synthesis at exponential phase would be the best choice of crRNA expression.</p>
<p>In the following days, we intend to use HPLC for analyzing the metabolic flux inside the cells, to clarify the impact of crRNA on metabolic flux. In addition, we may attempt to highly express crRNA, for the reason that based on the prediction made by modelling, PHB synthesis will be improved dramatically when gltA is inhibited by about 80 %. Under this condition, our growth-production switching system probably work very well. Also, since several catalytic steps are involved in order to transform acetyl-CoA into PHB, the metabolic flux may be complicated and thus reduce the effect of crRNA on metabolic flux redirection. Hence, we might also try some other easier examples. Like some biosynthesized material with less synthesis steps and simple metabolic flux to demonstrate the possibility of our system.</p>
+
  
 +
<p>After demonstrating the expression of phbCAB cluster and the effect of crRNA, we intend to combine light control PHB synthesis and <i>gltA</i> inhibition together for further demonstration of the possibility of our growth-production switching system in the future. Besides, we will also make use of the powerful technique, HPLC, to show the exact changes in metabolic flux after <i>gltA</i> is repressed by crRNA.</p>
  
 +
<h4 id="main-title">References<h4>
 +
<p>[1] Han, Tiyun, Quan Chen, and Haiyan Liu. "Engineered photoactivatable genetic switches based on the bacterium phage T7 RNA polymerase." ACS synthetic biology 6.2 (2016): 357-366.<br>
 +
[2] Baumschlager, Armin, Stephanie K. Aoki, and Mustafa Khammash. "Dynamic blue light-inducible T7 RNA polymerases (Opto-T7RNAPs) for precise spatiotemporal gene expression control." ACS synthetic biology 6.11 (2017): 2157-2167.<br>
 +
[3] Mitsuharu Nakajima, Stefano Ferri, Matthias Rögner and Koji Sode. "Construction of a Miniaturized Chromatic Acclimation Sensor from Cyanobacteria with Reversed Response to a Light Signal." Scientific Reports 6(2016):37595.<br>
 +
[4] Yizhao Chang, Tianyuan Su, Qingsheng Qi and Quanfeng Liang. ”Easy regulation of metabolic flux in Escherichia coli using an endogenous type I-E CRISPR-Cas system” Microb Cell Fact (2016) 15:195.<br>
 +
[5] Wang Q, Yu H, Xia Y, et al. Complete PHB mobilization in Escherichia coli enhances the stress tolerance: a potential biotechnological application[J]. Microbial cell factories, (2009), 8(1): 47.</p>
  
 
</div>
 
</div>

Latest revision as of 00:59, 8 December 2018

Results

Attempt to build the split RNAP

We initially chose a blue-light-controlled sensor as candidate. The sensor, opto T7 RNA polymerase is a pair of fusion proteins which initiates transcription of PT7 by dimerize when exposed to light 450 nm. nMag is fused with the CT (carbon terminal)[1] of T7RNAP and pMag is fused with NT (nitrogen terminal). Due to the toxicity of the part, the expression of both the two fusion proteins are induced by L-arabinose[2]. And we set a concentration gradient to explore the optimized condition.

1. Characterization of sensor opto T7 RNAP

We inserted the sfGFP after the PT7 to characterize the behavior of the blue light sensor. The experimental result shows no significant induction compared with the dark control.

Figure 1. Dynamic experiment of the expression level of Opto-T7RNAP. The sensor is exposed to blue light and dark respectively at 0h. Result showed no significant expression of sfGFP.
Figure 1. Dynamic experiment of the expression level of Opto-T7RNAP. The sensor is exposed to blue light and dark respectively at 0h. Result showed no significant expression of sfGFP.

2.Validation at protein level

To verify the expression of the sensors, whose MWs are 53.9kD and 78.5kD respectively. We tested the sample containing sensor induced by 0, 0.1%, 0.2%, 0.5% arabinose and empty vector. The SDS-PAGE result shows no significant existence of the sensors.

Figure 2. Analysis sensor expression in total E. coli protein by SDS PAGE.
Figure 2. Analysis sensor expression in total E. coli protein by SDS PAGE.

Characterization of CcaS/CcaR system

The CcaS protein acts as a light sensing part in CcaS/CcaR two-component system (TCS). CcaS consists of an N-terminal transmembrane helix; a GAF domain, which serves as the sensor domain; a linker region (L1); two PAS domains; a second linker region (L2); and a C-terminal histidine kinase (HK) domain. We were inspired by Professor Koji’s work[3] to remove the L1 linker region and the two PAS domains, then fuse the GAF and HK domains with a truncated linker region.

Figure 3. Domain organization of wild-type CcaS and miniaturized CcaSs.
Figure 3. Domain organization of wild-type CcaS and miniaturized CcaSs.

Our advanced system was characterized over wild type in M9 medium containing 2% glucose but without yeast extract. The fluorescence intensity was acquired 9 hours after inoculated into 24-well plate with Abs600 about 0.1. Our culture was exposed to different light to characterize different transcription level. The basic OD and fluorescence were wiped off. (n=3)

Figure 4. This figure shows the fluorescence of cells grown under green light (green bars), red light (red bars), and darkness (gray). Bars indicate relative fluorescence intensity to normalized fluorescence level of wild type. Data represent means ±SD from three repeat experiment (n=3).
Figure 4. This figure shows the fluorescence of cells grown under green light (green bars), red light (red bars). Bars indicate relative fluorescence intensity to normalized fluorescence level of wild type. Data represent means ±SD from three repeat experiment (n=3).

The dynamic ranges of green over red light of different system are: 2.8(wild type), 2.7(#3), 4.9(#10). The #4 has the reverse function and the dynamic range is about 1.5.

The construction of the metabolic flux regulation platform.

We selected type I-E CRISPRi system as the cut-over dynamically switching the metabolic flux. Type I-E CRISPRi system can inhibit the aimed gene’s transcription through expressing crRNA combining endogenous Cas protein.

1. Characterization of type I-E CRISPRi system

To remove the DNA degradation function and maintain the DNA binding function of the modified type I-E CRISPR system, a special E.coli TOP10 with Cas3 protein knocked out and promoter of Cascade substituted by promoter J23119 was constructed and named EE-E15. To verify the system in EE-E15, the GFP gene was chosen as a reporter to test the function of crRNA targeting different sites of GFP[4]. The results showed that there were wide rages of repression among different sites and the spacer posited on the promotor region presented high repression level (82%).

Figure 5. The site of spacers target gfp.
Figure 5. The site of spacers target gfp.
Figure 6. Characterization of type I-E CRISPRi system targeting different sites of gfp.
Figure 6. Characterization of type I-E CRISPRi system targeting different sites of gfp.

TCA cycle is one of the most significant metabolic pathways for energy supplement. The cycle starts with the process that citrate synthase catalyzes acetyl-coA and oxaloacetate to form citric, which is the rate-limiting step in the TCA cycle and irreversible, thus the regulation of expression of gltA which codes the citrate synthase may have great effect in central metabolism, and through model we also found that control of gltA can regulate the metabolic flux. We got the target site of gltA gene from previous work and then constructed a medium-copy plasmid (Paracr15A) and a high-copy plasmid (Paracr58.6) containing crRNA targeting gltA to inhibit expression. With 0.2% L-arabinose induction, the samples showed an obvious repression on growth compared with those without L-arabinose, regardless of the copy number difference between Paracr15A and Paracr58.6(Figure 8). Among them, aracr58.6 grew slower, which may due to its high leakage with high-copy plasmids. It indicated that this Type-I-E CRISPRi system can affect cell growth through producing crRNA targeting gltA.

Figure 7. The posited site of crRNA targeting gltA to inhibit it’s transcription.
Figure 7. The posited site of crRNA targeting gltA to inhibit it’s transcription.

Figure 8. Regulation effect of crRNA induced by L-arabinose between medium-copy and high-copy plasmids. The strains were cultured in 24-well plate in 1 ml M9 medium containing 1% glycerol.
Figure 8. Regulation effect of crRNA induced by L-arabinose between medium-copy and high-copy plasmids. The strains were cultured in 24-well plate in 1 ml M9 medium containing 1% glycerol.

2. light-induced type I-E CRISPRi system

Further, we utilized CcaS/CcaR sensor with type I-E CRISPRi system to induction of crRNA targeting the site of gltA through switching light. To optimize this system, we chose different culture medium verifying the function of light-induced crRNA.

Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates. Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates.
Figure 9. Comparison of the regulation effects between different carbon sources. Strains were cultured in 1ml M9 medium containing 1% glucose in a) while cultured in M9 medium with 1% glycerol in b) in 24-well plates.

In the figures we can find that cell cultured with glycerol growth had a higher level of repression compared with glucose. It indicates that crRNA targeting gltA to inhibit TCA cycle from the first step showed a better effect when nutrition was not directly utilized. In addition, it illustrates that condition made sense for the function of our system. Meanwhile the phenomenon was analyzed through flux balance analysis (FBA) mathematical model. With the data we found there was a threshold when inhibiting gltA, exceeding which appears an obvious transform in metabolic flux. We analyzed that glycerol as carbon source can reduce this threshold showing great repression which was in accordance with the growth results described above. Then we chose M9 medium with 1% glycerol as the condition for the characterization of crRNA targeting gltA.

To optimize the expression of crRNAs in EE-E15, then we constructed a medium-copy plasmid (pSR43.6) and high-copy plasmid (phz) to express crRNA targeting endogenous gltA. The two strains showed significant variance in growth in figure 4, suggesting crRNA on high-copy plasmid showed stronger repression than on medium-copy one. We supposed that the inhibition function was related to the quantity of crRNA and light-sensing promotor PcpG2-172 works well in high-copy number, leading to this result. It indicated that copy-number for light-induced crRNA had a great impact on this photoactivated regulation system.

Figure 10. Comparison of the regulatory effect between medium-copy and high-copy plasmids. #10 43.6 is a medium-copy plasmid (p15A ori) expressing crRNA while high-copy for #10 phz (CoIE1). The strains were cultured in 24-well plate in 1ml M9 medium containing 1% glycerol.
Figure 10. Comparison of the regulatory effect between medium-copy and high-copy plasmids. #10 43.6 is a medium-copy plasmid (p15A ori) expressing crRNA while high-copy for #10 phz (CoIE1). The strains were cultured in 24-well plate in 1ml M9 medium containing 1% glycerol.

After the verification of the culture condition, we investigated the dynamic regulation effects of targeting gltA with light-controlled system through switching red light to green light at 2h, 5h and 9h. As shown in figure 5, all strains induced at different time grow better compared with illuminating at 0h. Bacteria growth was inhibited the most when being induced at 5h, showing an obvious palliation after sensing green light. The strains induced at the early-log phase (2h) grew slower than the control (upon red illumination), whereas it continuously grew and maintained a relatively high K value. It was supposed that cells growing at a moderate speed at early consumed less nutrition, thus drove the biomass constantly increase and had a higher level of K value. In accordance with the hypothesis, we concluded the negative control without crRNA targeting gltA which presented a lowest level of K value consumed too much nutrition so that it can’t satisfy the need of cell in late period of growth. In addition, inducing crRNA expression at 9h through green light, we found there were little growth variance between the strains green light induced at 9h and the control illuminated at red light continuously. It was supposed that at the stationary phase there was nearly no effect for inhibiting TCA cycle to repress the cell’s growth, which might due to its metabolic flow. The difference between the regulation effect of different induction time isn’t obvious through light switching, might due to light sensor CcaS/CcaR system which only have 4.8-fold difference between red/green light induction.

Figure 11. Regulation effect of crRNA induced at different time by switching to green light. The strains were cultured in 50ml M9 medium containing 1% glycerol.
Figure 11. Regulation effect of crRNA induced at different time by switching to green light. The strains were cultured in 50ml M9 medium containing 1% glycerol.

We reconstructed EE-E15 driving its metabolic flux regulation at different time through switching red light to the green one. Then we made polyhydroxybutyrate(PHB) as an example to demonstrate our dynamically regulating metabolic flux platform.

PHB fermentation


1. PHB synthesis with CcaS/CcaR system

Firstly, in order to verify that phbCAB cluster could be expressed induced by CcaS/CcaR system and synthesize Polyhydroxybutyrate (PHB) successfully, phbCAB cluster (without its original constitutive promoter) was cloned right behind the light sensing promoter, PcpcG2-172 (Figure 12).

Figure 12. Gene circuit of "PHB induced”

Also strain “PHB induced Red/Green” was illuminated with red light and green light respectively throughout the PHB fermentation while light illuminating “PHB induced 5h” was switched from red light to green light at 5h (exponential phase) so that we can tell whether turning on PHB synthesis pathway at different periods could affect PHB content within the cells and cell growth, as well.


Figure 13.Cell growth curve and PHB production among strain “PHB induced”. In groups "PHB induced 5h/Green", the expression of phbCAB is activated at 0h and 5h respectively. In contrast "PHB induced Red" are illuminated by red light throughout the fermentation to inhibit the crRNA expression. (a) cell growth curve during the PHB fermentation. (b) the ratio between PHB and cell drought weight, showing the average PHB content within each cell. (c) total amount of PHB produced during the fermentation.

According to the PHB fermentation results, CcaS/CcaR system expressed phbCAB cluster successfully (Figure 13.b c). What’s more, a large amount of PHB could be synthesized as PHB took up over 30% of cell drought at the end of fermentation in “PHB induced Green" (Figure 13.b). Furthermore, the amount of PHB inside the cells increased as the amount of time for phbCAB cluster expression increased, which was consistent with our expectation (Figure 13.b). However, to our surprise, it appeared that those groups containing higher PHB content tended to grow better than those with less PHB. After searching articles on the relationship between PHB synthesis and bacteria stress tolerance, we found out that the biosynthesized PHB stored inside the cell can serve as an intracellular energy and carbon storage system and thus, increases the cell survival rate when carbon source is limited.[5] This probably explains the reason why the “PHB induced” that synthesized more PHB tend to have higher cell density for the duration of fermentation.

2. Effect of metabolic flux redirection on PHB production

Since we have demonstrated that a great deal of PHB can be synthesized under the control of CcaS/CcaA system, we then hope to verify that the inhibition of gltA gene by crRNA as well as type I-E CRISPRi system can improve PHB production through metabolic flux redirection. Therefore, we constructed another E. coli strain, “PHB con+crRNA”, which expresses phbCAB constitutively with its original promoter within the operon and expresses crRNA through CcaS/CcaA system (Figure 14).

Figure 14. Gene circuit of “PHB con+crRNA”

Furthermore, the expression of crRNA was turned on at different periods of PHB fermentation. To be more specific, “PHB con+crRNA 5h/13.5h” expressed crRNA at 5h (exponential phase) and 13.5h (stationary phase) respectively by switching from red light illumination into green light. And besides, “PHB con+crRNA Red” was illuminated with red light all the time while “PHB con+crRNA Green” expressed crRNA throughout the fermentation (lag phase).


Figure 15. Cell growth curve and PHB production of strain “PHB con+crRNA”. In "PHB con+crRNA Green/5h/13.5h", the expression of crRNA is activated at the beginning (0h), 5h and 13.5h respectively. By contrast, "PHB con+crRNA Red" is incubated under red light all the time to suppress crRNA expression. (a) the cell growth curve during the PHB fermentation. (b) the ratio between PHB and cell drought weight. (c) total amount of PHB produced during the fermentation.

As we can see, despite “PHB con+crRNA Red” grew slightly better than the other, there was no significant difference between “PHB con+crRNA Green/5h/13.5h” (Figure 15. a), which meant that unlike the results shown on crRNA characterization, here, crRNA doesn’t inhibit cell grow. Based on the former PHB fermentation result, this was probably because the PHB synthesized by E. coli also has a positive effect on cell growth which offsets the detrimental impact of crRNA. And since crRNA was just expressed at a leaky level, “PHB con+crRNA Red” seems to grow slightly better than the other groups.

With respect to PHB production, “PHB con+crRNA Red” with leaky expression of crRNA produced less PHB showing that the inhibition of gltA gene by crRNA improved PHB production dramatically (Figure 15. b c). And more importantly, the amount of PHB within the cells is different among different “PHB con+crRNA” group (Figure 15. b). That’s to say, the expressing crRNA at different periods of fermentation might lead to the variation of PHB content. In addition, “PHB con+crRNA 5h” tended to produce more PHB as shown in the data (Figure 15. b c) in comparison to “PHB con+crRNA Green/13.5h”. Thus, we can express crRNA at exponential phase to improve PHB production while turning on crRNA at stationary phase would be a bad choice.

In short, expressing crRNA can improve PHB synthesis at exponential phase would be the best choice of crRNA expression.

After demonstrating the expression of phbCAB cluster and the effect of crRNA, we intend to combine light control PHB synthesis and gltA inhibition together for further demonstration of the possibility of our growth-production switching system in the future. Besides, we will also make use of the powerful technique, HPLC, to show the exact changes in metabolic flux after gltA is repressed by crRNA.

References

[1] Han, Tiyun, Quan Chen, and Haiyan Liu. "Engineered photoactivatable genetic switches based on the bacterium phage T7 RNA polymerase." ACS synthetic biology 6.2 (2016): 357-366.
[2] Baumschlager, Armin, Stephanie K. Aoki, and Mustafa Khammash. "Dynamic blue light-inducible T7 RNA polymerases (Opto-T7RNAPs) for precise spatiotemporal gene expression control." ACS synthetic biology 6.11 (2017): 2157-2167.
[3] Mitsuharu Nakajima, Stefano Ferri, Matthias Rögner and Koji Sode. "Construction of a Miniaturized Chromatic Acclimation Sensor from Cyanobacteria with Reversed Response to a Light Signal." Scientific Reports 6(2016):37595.
[4] Yizhao Chang, Tianyuan Su, Qingsheng Qi and Quanfeng Liang. ”Easy regulation of metabolic flux in Escherichia coli using an endogenous type I-E CRISPR-Cas system” Microb Cell Fact (2016) 15:195.
[5] Wang Q, Yu H, Xia Y, et al. Complete PHB mobilization in Escherichia coli enhances the stress tolerance: a potential biotechnological application[J]. Microbial cell factories, (2009), 8(1): 47.