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Team:UT-Tokyo/Counter/Project/Result
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<sigma factor> | <sigma factor> | ||
<h3>influence on growth of E. coli</h3> | <h3>influence on growth of E. coli</h3> | ||
| - | <p>We chose two sigma factors, ecf20 (BBa_K1461004) and ecf11 (BBa_K1461005), which have no influence on the growth of E. coli based on a previous research[1].</p> | + | <p>We chose two sigma factors, ecf20 (BBa_K1461004) and ecf11 (BBa_K1461005), which have no influence on the growth of E. coli based on a previous research[1]. Then, we can expect that there will be no defference between the growth curve of the cells which express sigma factors and do not.</p> |
| - | <legend><b>Fig. 1</b> The | + | <legend><b>Fig. 1</b> The growth curve of the cells which express sigma factors and do not. Arabinose was added 3 hours after the inoculation. "None" means pSB1C3 plasmid without insert sequence. Error bar shows average ± SE. N = 5. </legend> |
<p>However, as seen in Figure 1, we found that ecf20 had repressive influence on growth of E. coli. This result, which did not meet that of the previous research, may be caused by the difference of strain of E.coli or the medium used in the measurement. We used MG1655 and M9 medium, while the previous researchers used DH10b and LB medium.</p> | <p>However, as seen in Figure 1, we found that ecf20 had repressive influence on growth of E. coli. This result, which did not meet that of the previous research, may be caused by the difference of strain of E.coli or the medium used in the measurement. We used MG1655 and M9 medium, while the previous researchers used DH10b and LB medium.</p> | ||
<p>Although we found that ecf20 repressed the growth of E. coli, the influence may not be so large as to change general behaviour of our device. In the presence of ecf20, E. coli's growth rate became slower and the maximum concentration became lower a little, but not critically. </p> | <p>Although we found that ecf20 repressed the growth of E. coli, the influence may not be so large as to change general behaviour of our device. In the presence of ecf20, E. coli's growth rate became slower and the maximum concentration became lower a little, but not critically. </p> | ||
| - | <h3>sigma factor and its | + | <h3>sigma factor and its corresponding promoter</h3> |
| - | <p>In order to test the | + | <p>In order to test whether the sigma factors activate only their corresponding promoters, and whether the promoters was activated only by their corresponding sigma factors, we introduced various combinations of sigma factor (induced by arabinose) and promoter (reported by GFP) into E. coli.</p> |
| - | <legend><b>Fig. 2</b> | + | <legend><b>Fig. 2</b> GFP fluorescence reporting the activities of various combinations of sigma factors and promoters. GFP was activated by 488 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 3. </legend> |
| - | <p>As seen in Figure 2, ecf20 and ecf11 | + | <p>As seen in Figure 2, ecf20 and ecf11 activated only their corresponding promoters. Leak from the promoters was also not observed. The result of the sample whose sigma factor was not induced by arabinose (ara-), which had little difference from the one induced by arabinose (ara+), may be caused by the leak of pBAD (BBa_I13453). The amount of the sigma factor leaked from pBAD may be over the switch-point of sigmoid curve indicating relation between sigma factor and its corresponding promoter. Thus, even if the amount of sigma factor changes by arabinose induction, corresponding activity of promoter may not change.</p> |
</div> | </div> | ||
<div id = "Result-2"> | <div id = "Result-2"> | ||
<reset function> | <reset function> | ||
| - | <p>We tested the | + | <p>We tested whether the anti-sigmas (induced by IPTG) repress the activation of the promoters by their corresponding sigma factors.</p> |
| - | <legend><b>Fig. 3</b> | + | <legend><b>Fig. 3</b> GFP fluorescence coded by the promoters activated by their corresponding sigma factors under the existence/abstance of their corresponding anti-sigma factors. GFP was activated by 488 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 3. </legend> |
| - | <p>Unexpectedly, the culture of cells containing the genes of the reset function showed no difference from that without reset function. This result may indicate that the sigma factors were expressed more than the anti-sigma factors could repress their activation of the | + | <p>Unexpectedly, the culture of cells containing the genes of the reset function showed no difference from that without reset function. This result may indicate that the sigma factors were expressed more than the anti-sigma factors could repress their activation of the corresponding promoters.</p> |
</div> | </div> | ||
<div id = "Result-3"> | <div id = "Result-3"> | ||
<riboregulator> | <riboregulator> | ||
| - | <p>In order to test the riboregulator system, we constructed a genetic circuit containing constitutively transcribed crRNA coding GFP and taRNA (arabinose induced).</p> | + | <p>In order to test the riboregulator system, we constructed a genetic circuit containing constitutively transcribed crRNA coding GFP and taRNA (arabinose induced). We make the genetic circuit coding only crRNA, not coding taRNA, as control. We can expect the cells will express GFP by arabinose induction. </p> |
| - | <legend><b>Fig. 4</b> | + | <legend><b>Fig. 4</b> GFP fluorescence coded by constitutively transcribed crRNA under exitence/absence of taRNA. "None" means pSB1C3 with no insert sequence as negative control. GFP was activated by 501 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 5. </legend> |
| - | <p> | + | <p>The difference between the samples was not significant, which means the riboregulator system did not work. Several factors can be suggested for the reason why this device did not work, such as the incubation temperature, the amount of transcribed taRNA relative to that of crRNA. (Although we tried at various temperature, we could not see any fluorescence.)</p> |
</div> | </div> | ||
<div id = "Result-4"> | <div id = "Result-4"> | ||
| - | + | <positive feedback> | |
| - | <p>To test whether the positive feedback of sigma factor can keep the | + | <p>To test whether the positive feedback of sigma factor can keep the sigma factors expressed after the arabinose induction was stopped, we added arabinose for some length of time to the cultures of cells containing/not containing positive feedback of sigma factors.</p> |
| - | <legend><b>Fig. 5</b> | + | <legend><b>Fig. 5</b> GFP fluorescence coded by the promoter and the corresponding sigma factor with/without positive feedback of the sigma factor. GFP was excited by 488 nm excitation laser and the activity was measured by 514 nm emission laser. N = 1. </legend> |
<p>Unexpectedly, the genetic circuit with positive feedback showed no fluorescence. The sequence of this construct was not confirmed (since the degradation tag was added by PCR at the final step of DNA assembly and the primers for sequencing had not been prepared before deadline), and we thought some mutations made this result.</p> | <p>Unexpectedly, the genetic circuit with positive feedback showed no fluorescence. The sequence of this construct was not confirmed (since the degradation tag was added by PCR at the final step of DNA assembly and the primers for sequencing had not been prepared before deadline), and we thought some mutations made this result.</p> | ||
</div> | </div> | ||
<div id = "Result-5"> | <div id = "Result-5"> | ||
<conclusion> | <conclusion> | ||
| - | <p>From figure1, we suggest that | + | <p>From figure1, we suggest that even so low concentration of sigma factors as the leak from pBAD can activate the corresponding promoters. For the realization of our device, change of the promoter coding sigma factor or the backbone whose parameters are appropriate may be necessary. The strain of the host cell is also thought to be one of the important factors. These selections are the future works.</p> |
</div> | </div> | ||
Revision as of 20:08, 17 October 2014
<sigma factor>
influence on growth of E. coli
We chose two sigma factors, ecf20 (BBa_K1461004) and ecf11 (BBa_K1461005), which have no influence on the growth of E. coli based on a previous research[1]. Then, we can expect that there will be no defference between the growth curve of the cells which express sigma factors and do not.
<legend>Fig. 1 The growth curve of the cells which express sigma factors and do not. Arabinose was added 3 hours after the inoculation. "None" means pSB1C3 plasmid without insert sequence. Error bar shows average ± SE. N = 5. </legend>
However, as seen in Figure 1, we found that ecf20 had repressive influence on growth of E. coli. This result, which did not meet that of the previous research, may be caused by the difference of strain of E.coli or the medium used in the measurement. We used MG1655 and M9 medium, while the previous researchers used DH10b and LB medium.
Although we found that ecf20 repressed the growth of E. coli, the influence may not be so large as to change general behaviour of our device. In the presence of ecf20, E. coli's growth rate became slower and the maximum concentration became lower a little, but not critically.
sigma factor and its corresponding promoter
In order to test whether the sigma factors activate only their corresponding promoters, and whether the promoters was activated only by their corresponding sigma factors, we introduced various combinations of sigma factor (induced by arabinose) and promoter (reported by GFP) into E. coli.
<legend>Fig. 2 GFP fluorescence reporting the activities of various combinations of sigma factors and promoters. GFP was activated by 488 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 3. </legend>
As seen in Figure 2, ecf20 and ecf11 activated only their corresponding promoters. Leak from the promoters was also not observed. The result of the sample whose sigma factor was not induced by arabinose (ara-), which had little difference from the one induced by arabinose (ara+), may be caused by the leak of pBAD (BBa_I13453). The amount of the sigma factor leaked from pBAD may be over the switch-point of sigmoid curve indicating relation between sigma factor and its corresponding promoter. Thus, even if the amount of sigma factor changes by arabinose induction, corresponding activity of promoter may not change.
<reset function>
We tested whether the anti-sigmas (induced by IPTG) repress the activation of the promoters by their corresponding sigma factors.
<legend>Fig. 3 GFP fluorescence coded by the promoters activated by their corresponding sigma factors under the existence/abstance of their corresponding anti-sigma factors. GFP was activated by 488 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 3. </legend>
Unexpectedly, the culture of cells containing the genes of the reset function showed no difference from that without reset function. This result may indicate that the sigma factors were expressed more than the anti-sigma factors could repress their activation of the corresponding promoters.
<riboregulator>
In order to test the riboregulator system, we constructed a genetic circuit containing constitutively transcribed crRNA coding GFP and taRNA (arabinose induced). We make the genetic circuit coding only crRNA, not coding taRNA, as control. We can expect the cells will express GFP by arabinose induction.
<legend>Fig. 4 GFP fluorescence coded by constitutively transcribed crRNA under exitence/absence of taRNA. "None" means pSB1C3 with no insert sequence as negative control. GFP was activated by 501 nm excitation laser and the activity was measured by 514 nm emission laser. Error bar shows average ± SE. N = 5. </legend>
The difference between the samples was not significant, which means the riboregulator system did not work. Several factors can be suggested for the reason why this device did not work, such as the incubation temperature, the amount of transcribed taRNA relative to that of crRNA. (Although we tried at various temperature, we could not see any fluorescence.)
<positive feedback>
To test whether the positive feedback of sigma factor can keep the sigma factors expressed after the arabinose induction was stopped, we added arabinose for some length of time to the cultures of cells containing/not containing positive feedback of sigma factors.
<legend>Fig. 5 GFP fluorescence coded by the promoter and the corresponding sigma factor with/without positive feedback of the sigma factor. GFP was excited by 488 nm excitation laser and the activity was measured by 514 nm emission laser. N = 1. </legend>
Unexpectedly, the genetic circuit with positive feedback showed no fluorescence. The sequence of this construct was not confirmed (since the degradation tag was added by PCR at the final step of DNA assembly and the primers for sequencing had not been prepared before deadline), and we thought some mutations made this result.
<conclusion>
From figure1, we suggest that even so low concentration of sigma factors as the leak from pBAD can activate the corresponding promoters. For the realization of our device, change of the promoter coding sigma factor or the backbone whose parameters are appropriate may be necessary. The strain of the host cell is also thought to be one of the important factors. These selections are the future works.
