Difference between revisions of "Part:BBa K2918040"

(Usage and Biology)
(References)
 
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</center>
 
</center>
 
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iFFL can be applied to genetic circuits to achieve expression independent from copy number, transcriptional and translational rates. To implement the iFFL in a genetic circuit, TALE proteins can be used. These proteins consist of repeats where 12th and 13th amino acids can vary, these are called the repeat variable diresidue (RVD). RVDs have been shown to bind to DNA in a simple one-to-one binding code <html><a href="#Doyle2013">(Doyle, Stoddard et al., 2013)</a></html>. The direct correspondence between amino acids allows scientists to engineer these repeat regions to target any sequence they want. In our system, we used the TALE protein as a repressor by engineering promoters to contain the binding site of this specific TALE protein (<html><a href="https://parts.igem.org/Part:BBa_K2918010">Medium T7sp1 promoter</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K2918011">P<sub>BHR</sub>sp1 promoter</a></html>). <br> In our genetic circuit, a unrepressed promoter controls the expression of TALE protein while the promoters with the TALE binding sites drive expression of GFP. <br><br>
+
iFFL can be applied to genetic circuits to achieve expression independent from copy number, transcriptional and translational rates. To implement the iFFL in a genetic circuit, TALE proteins can be used. These proteins consist of repeats where 12th and 13th amino acids can vary, these are called the repeat variable diresidue (RVD). RVDs have been shown to bind to DNA in a simple one-to-one binding code <html><a href="#Doyle2013">(Doyle, Stoddard et al., 2013)</a></html>. The direct correspondence between amino acids allows scientists to engineer these repeat regions to target any sequence they want. In our system, we used the TALE protein as a repressor by engineering promoters to contain the binding site of this specific TALE protein (<html><a href="https://parts.igem.org/Part:BBa_K2918010">T7sp1 promoter</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K2918011">P<sub>BHR</sub>sp1 promoter</a></html>). <br> In our genetic circuit, a unrepressed promoter controls the expression of TALE protein while the promoters with the TALE binding sites drive expression of GFP. <br><br>
  
 
<div><ul>  
 
<div><ul>  
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     </ul></div>
 
     </ul></div>
  
When transcriptional units are placed in series due to low effieciency of terminators, leaky expression of the gene in the neighboring transcriptonal unit can occur. This significantly influences the behavior of the iFFL genetic circuit as predicted by our <html><body><a target="_blank" href="https://2019.igem.org/Team:TUDelft/Model">model</a></body></html>. Hence, the transcriptional unit of TALE is oriented in a different orientation than the transcriptional unit of GFP (as shown in Figure 2).  
+
When transcriptional units are placed in series due to low effieciency of terminators, leaky expression of the gene in the neighboring transcriptonal unit can occur. This significantly influences the behavior of the iFFL genetic circuit as predicted by our <html><a target="_blank" href="https://2019.igem.org/Team:TUDelft/Model">model</a></html>. Hence, the transcriptional unit of TALE is oriented in a different orientation than the transcriptional unit of GFP (as shown in Figure 2).  
  
An interesting application of the iFFL is to achieve controllable gene expression across different bacterial species. Gene expression in different bacterial contexts is influenced by changes in copy number, transcriptional and translational rates. To achieve expression robust to changes in transcriptional and tranlational rates, the ratio of transcriptional and translational rates of GFP and repressor need to be constant. This can be achieved by using orthogonal T7 promoter and its variants (<html><a href="https://parts.igem.org/Part:BBa_K2918053">T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918005">0.5 T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918006">0.1 T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918009">0.5 T7sp1 promoter</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K2918010">T7sp1 promoter</a></html> ).   
+
An interesting application of the iFFL is to achieve controllable gene expression across different bacterial species. Gene expression in different bacterial contexts is influenced by changes in copy number, transcriptional and translational rates. To achieve expression robust to changes in transcriptional and tranlational rates, the ratio of transcriptional and translational rates of GFP and repressor need to be constant. This can be achieved by using orthogonal T7 promoter and its variants (<html><a href="https://parts.igem.org/Part:BBa_K2918053">T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918005">Weak T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918006">Medium T7 promoter</a></html>, <html><a href="https://parts.igem.org/Part:BBa_K2918009">Medium T7sp1 promoter</a></html> and <html><a href="https://parts.igem.org/Part:BBa_K2918010">T7sp1 promoter</a></html>).   
  
Apart from being able to achieve stable gene expression across different bacterial species, it is necessary to attain  different levels of gene expression. The T7 promoter based optimized iFFL can be used to obtain higher levels of gene of interest (GFP) expression as the expression of TALE is driven by a lower strength promoter (0.1 T7 promoter) compared to the promoter (0.5 T7sp1 promoter) driving GFP expression.
+
Apart from being able to achieve stable gene expression across different bacterial species, it is necessary to attain  different levels of gene expression. The T7 promoter based optimized iFFL can be used to obtain higher levels of gene of interest (GFP) expression as the expression of TALE is driven by a lower strength promoter (Weak T7 promoter) compared to the promoter (Medium T7sp1 promoter) driving GFP expression.
  
 
===Strain Construction===
 
===Strain Construction===
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<b>Note: The basic parts sequences of the Sci-Phi 29 collection in the registry contain only the part sequence and therefore contain no overhangs or restriction sites. For synthesizing MoClo compatible parts, refer to table 2. The complete sequence of our parts including backbone can be found <html><a href="http://2019.igem.org/Team:TUDelft/Experiments" target="_blank">here</a>.</html></b>
+
<b>Note: The basic parts sequences of the Sci-Phi 29 collection in the registry contain only the part sequence and therefore contain no overhangs or restriction sites. For synthesizing MoClo compatible parts, refer to table 2.</b>
  
  
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===Characterization===
 
===Characterization===
 
<p>  
 
<p>  
According to our <html><body><a href="https://2019.igem.org/Team:TUDelft/Model">model</a></body></html>, the genetic implementation of the iFFL system yields the same gene of interest (GOI) expression levels when the transcription rate of both genes (TALE and GOI) are changed in the same ratio as can be seen in Figure 3. </p>
+
According to our <html><a target="_blank" href="https://2019.igem.org/Team:TUDelft/Model">model</a></html>, the genetic implementation of the iFFL system yields the same gene of interest (GOI) expression levels when the transcriptional rate of both genes (TALE and GOI) are changed in the same ratio as can be seen in Figure 3. </p>
 
<div><ul>  
 
<div><ul>  
 
<center>
 
<center>
   <li style="display: inline-block;"> [[File:T--TUDelft--transcriptionvariation1.jpg|thumb|none|550px|<b>Figure 3</b>: Steady-state GFP production while transcription rates of both TALE and GOI are changed. The lines indicate constant ratio of transcription rates]] </li>
+
   <li style="display: inline-block;"> [[File:T--TUDelft--transcriptionvariation1.jpg|thumb|none|550px|<b>Figure 3</b>: Steady-state GFP production while transcriptional rates of both TALE and GOI are changed. The lines indicate constant ratio of transcriptional rates]] </li>
 
</center>
 
</center>
 
     </ul></div>  
 
     </ul></div>  
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<p>For the system to be versatile, it is important to achieve different levels of output gene expression (GFP). Hence, in the optimized iFFL system the TALE repressor is expressed by a higher strength promoter compared to the promoter controlling GFP expression. </p>
 
<p>For the system to be versatile, it is important to achieve different levels of output gene expression (GFP). Hence, in the optimized iFFL system the TALE repressor is expressed by a higher strength promoter compared to the promoter controlling GFP expression. </p>
  
<p> To validate the insulation of the gene expression (GFP) in the iFFL system to changes in transcriptional rates, GFP fluorescence was measured at different IPTG concentrations by flow cytometry at log-phase of growth. Change in IPTG concentrations, changes in-vivo concentrations of T7 RNAP and this contributes to variations in transcriptional rates. In unrepressed systems, the expression of the GOI is a function of IPTG concentrations. However, in iFFL systems due to the expression of TALE repressor, similar GFP expression across different IPTG concentrations is expected. </p>
+
<p> To validate the insulation of the gene expression (GFP) in the iFFL system to changes in transcriptional rates, GFP fluorescence was measured at different IPTG concentrations by flow cytometry at log-phase of growth. Change in IPTG concentrations, changes <I>in vivo</I> concentrations of T7 RNAP and this contributes to variations in transcriptional rates. In unrepressed systems, the expression of the GOI is a function of IPTG concentrations. However, in iFFL systems due to the expression of TALE repressor, similar GFP expression across different IPTG concentrations is expected. </p>
  
<p> The iFFL system was validated by measuring GFP using flow cytometry. As a control, GFP under the control of T7sp1 promoter was used. As a reference for background fluorescence, <i>E.coli</i> BL21(DE3) cells without plasmids were used. The protocol for sample preparation can be found <html><body><a href="https://2019.igem.org/Team:TUDelft/Experiments">here</a></body></html>.</p>
+
<p> The iFFL system was validated by measuring GFP using flow cytometry. As a control, GFP under the control of T7sp1 promoter was used. As a reference for background fluorescence, <i>E. coli</i> BL21(DE3) cells without plasmids were used. The protocol for sample preparation can be found <html><body><a href="https://2019.igem.org/Team:TUDelft/Experiments">here</a></body></html>.</p>
  
 
<p> Scatter plots (Figures 7 and 8) for the unprepressed control and T7 based optimized iFFL were gated by eye to select for the most dense regions. Figures 4 and 5 show fluorescence measurements for the gated populations of the unrepressed control and optimized iFFL system at different IPTG concentrations respectively. </p>  
 
<p> Scatter plots (Figures 7 and 8) for the unprepressed control and T7 based optimized iFFL were gated by eye to select for the most dense regions. Figures 4 and 5 show fluorescence measurements for the gated populations of the unrepressed control and optimized iFFL system at different IPTG concentrations respectively. </p>  
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<div><ul>  
 
<div><ul>  
 
<center>
 
<center>
   <li style="display: inline-block;"> [[File:T--TUDelft--L1etafluorescence.png|thumb|none|550px|<b>Figure 4</b>: Flourescence measurements from gated population of unrepressed control (for scatter plot refer Figure 7) at different IPTG concentrations. Black: <i>E.coli</i>BL21(DE3)(Green: 0mM, Red: 0.1mM, Blue: 0.5mM and Purple: 1mM ]] </li>
+
   <li style="display: inline-block;"> [[File:T--TUDelft--L1etafluorescence.png|thumb|none|550px|<b>Figure 4</b>: Fluorescence measurements from gated population of unrepressed control (for scatter plot refer Figure 7) at different IPTG concentrations. Black: <i>E. coli</I> BL21(DE3)(Green: 0mM, Red: 0.1mM, Blue: 0.5mM and Purple: 1mM ]] </li>
 
</center>
 
</center>
 
     </ul></div>  
 
     </ul></div>  
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<div><ul>  
 
<div><ul>  
 
<center>
 
<center>
   <li style="display: inline-block;"> [[File:T--TUDelft--LM23fluorescence.png|thumb|none|550px|<b>Figure 5</b>: Flourescence measurements from gated population of optimized iFFL system (for scatter plot refer Figure 8) at different IPTG concentrations. Black: <i>E.coli</i>BL21(DE3), Green: 0mM, Red:0.1mM, Blue: 0.5mM and Purple: 1mM ]] </li>
+
   <li style="display: inline-block;"> [[File:T--TUDelft--LM23fluorescence.png|thumb|none|550px|<b>Figure 5</b>: Fluorescence measurements from gated population of optimized iFFL system (for scatter plot refer Figure 8) at different IPTG concentrations. Black: <i>E. coli</I> BL21(DE3), Green: 0mM, Red:0.1mM, Blue: 0.5mM and Purple: 1mM ]] </li>
 
</center>
 
</center>
 
     </ul></div>  
 
     </ul></div>  
<p> In Figure 4, it is seen that GFP fluroscence of the unrepressed control changes with IPTG concentrations. However,(in Figure 5) for the optimized iFFL system, the GFP fluroscence curves for all the IPTG concentrations overlap and therefore is independent of IPTG concentrations. </p>  
+
<p> In Figure 4, it is seen that GFP fluorescence of the unrepressed control changes with IPTG concentrations. However,(in Figure 5) for the optimized iFFL system, the GFP fluorescence curves for all the IPTG concentrations overlap and therefore is independent of IPTG concentrations. </p>  
  
 
<div><ul>  
 
<div><ul>  
 
<center>
 
<center>
   <li style="display: inline-block;"> [[File:T--TUDelft--IPTGtitration.png|thumb|none|550px|<b>Figure 6</b>: Steady state GFP flourescnece measurements using flow cytometry at different IPTG concentrations. Measurements were made at log-phase of growth and the median flourescence of the gated populations is plotted. ]] </li>
+
   <li style="display: inline-block;"> [[File:T--TUDelft--IPTGtitration.png|thumb|none|550px|<b>Figure 6</b>: Steady state GFP fluorescnece measurements using flow cytometry at different IPTG concentrations. Measurements were made at log-phase of growth and the median fluorescence of the gated populations is plotted. ]] </li>
 
</center>  
 
</center>  
 
</ul></div>   
 
</ul></div>   
  
<p> From Figure 6, it is seen that despite changes in IPTG the GFP fluroscence remains the same while the GFP fluroscence of the control increases with IPTG concentrations. This suggests that the gene of interest expression is independent of in-vivo T7 RNAP concentrations (IPTG concentrations) thereby independent of changes in transcriptional rate. </p>
+
<p> From Figure 6, it is seen that despite changes in IPTG the GFP fluorescence remains the same while the GFP fluorescence of the control increases with IPTG concentrations. This suggests that the gene of interest expression is independent of in-vivo T7 RNAP concentrations (IPTG concentrations) thereby independent of changes in transcriptional rate. </p>
  
 
===Conclusion===
 
===Conclusion===
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Doyle, E. L., Hummel, A. W., Demorest, Z. L., Starker, C. G., Voytas, D. F., Bradley, P., & Bogdanove, A. J. (2013). TAL Effector Specificity for base 0 of the DNA Target Is Altered in a Complex, Effector- and Assay-Dependent Manner by Substitutions for the Tryptophan in Cryptic Repeat –1. <i>PLoS ONE</i>, 8(12).</a>
 
Doyle, E. L., Hummel, A. W., Demorest, Z. L., Starker, C. G., Voytas, D. F., Bradley, P., & Bogdanove, A. J. (2013). TAL Effector Specificity for base 0 of the DNA Target Is Altered in a Complex, Effector- and Assay-Dependent Manner by Substitutions for the Tryptophan in Cryptic Repeat –1. <i>PLoS ONE</i>, 8(12).</a>
 
</li>
 
</li>
<li>
 
<a id="Segall2018" href="https://www.nature.com/articles/nbt.4111" target="_blank">
 
Segall-Shapiro, T. H., Sontag, E. D., & Voigt, C. A. (2018). Engineered promoters enable constant gene expression at any copy number in bacteria. <i>Nature Biotechnology</i>, 36(4), 352–358.</a>
 
</li>
 
<li>
 
<a id="komura2018" href="https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0196905">Komura, R., Aoki, W., Motone, K., Satomura, A., & Ueda, M. (2018). High-throughput evaluation of T7 promoter variants using biased randomization and DNA barcoding. Plos One, 13(5). doi: 10.1371/journal.pone.019690</a></li>
 
  
 
</ul>
 
</ul>

Latest revision as of 20:56, 6 December 2019

T7 promoter based optimized iFFL

Genetic implementation of an incoherent feed-forward loop (iFFL) in which a weak strength T7 promoter with a binding site for TALE is controlling GFP expression.

Sequence and Features


Assembly Compatibility:
  • 10
    INCOMPATIBLE WITH RFC[10]
    Illegal PstI site found at 283
    Illegal PstI site found at 2538
  • 12
    INCOMPATIBLE WITH RFC[12]
    Illegal PstI site found at 283
    Illegal PstI site found at 2538
  • 21
    INCOMPATIBLE WITH RFC[21]
    Illegal XhoI site found at 250
    Illegal XhoI site found at 3335
  • 23
    INCOMPATIBLE WITH RFC[23]
    Illegal PstI site found at 283
    Illegal PstI site found at 2538
  • 25
    INCOMPATIBLE WITH RFC[25]
    Illegal PstI site found at 283
    Illegal PstI site found at 2538
    Illegal AgeI site found at 1277
  • 1000
    COMPATIBLE WITH RFC[1000]

The two transcriptional units in this composite part are oriented outwards.

Usage and Biology

An incoherent feed-forward loop (iFFL) is a unique control systems motif where the output signal is robust to changes in the input signal (as shown in Figure 1). This is achieved by the introduction of a repressor.

  • Figure 1: Overview of incoherent feed-forward loop

iFFL can be applied to genetic circuits to achieve expression independent from copy number, transcriptional and translational rates. To implement the iFFL in a genetic circuit, TALE proteins can be used. These proteins consist of repeats where 12th and 13th amino acids can vary, these are called the repeat variable diresidue (RVD). RVDs have been shown to bind to DNA in a simple one-to-one binding code (Doyle, Stoddard et al., 2013). The direct correspondence between amino acids allows scientists to engineer these repeat regions to target any sequence they want. In our system, we used the TALE protein as a repressor by engineering promoters to contain the binding site of this specific TALE protein (T7sp1 promoter and PBHRsp1 promoter).
In our genetic circuit, a unrepressed promoter controls the expression of TALE protein while the promoters with the TALE binding sites drive expression of GFP.

  • Figure 2: Overview of how the TALE proteins represses GFP

When transcriptional units are placed in series due to low effieciency of terminators, leaky expression of the gene in the neighboring transcriptonal unit can occur. This significantly influences the behavior of the iFFL genetic circuit as predicted by our model. Hence, the transcriptional unit of TALE is oriented in a different orientation than the transcriptional unit of GFP (as shown in Figure 2).

An interesting application of the iFFL is to achieve controllable gene expression across different bacterial species. Gene expression in different bacterial contexts is influenced by changes in copy number, transcriptional and translational rates. To achieve expression robust to changes in transcriptional and tranlational rates, the ratio of transcriptional and translational rates of GFP and repressor need to be constant. This can be achieved by using orthogonal T7 promoter and its variants (T7 promoter, Weak T7 promoter, Medium T7 promoter, Medium T7sp1 promoter and T7sp1 promoter).

Apart from being able to achieve stable gene expression across different bacterial species, it is necessary to attain different levels of gene expression. The T7 promoter based optimized iFFL can be used to obtain higher levels of gene of interest (GFP) expression as the expression of TALE is driven by a lower strength promoter (Weak T7 promoter) compared to the promoter (Medium T7sp1 promoter) driving GFP expression.

Strain Construction

The construct was assembled by golden gate assembly based modular cloning system. First, the individual transcriptional units were cloned into level 1 destination vectors pICH47761 and pICH47822 by BsaI based golden gate assembly. The multi-transcriptional unit construct was assembled by a BpiI based golden gate. The assembly was a one-pot restriction-ligation reaction where the individual level 1 constructs were added along with the destination vector pICH48055. The correct clone was distinguished by blue-white screening and the construct was confirmed by sequencing. The cloning protocol can be found in the MoClo section below.

Modular Cloning

Modular Cloning (MoClo) is a system which allows for efficient one pot assembly of multiple DNA fragments. The MoClo system consists of Type IIS restriction enzymes that cleave DNA 4 to 8 base pairs away from the recognition sites. Cleavage outside of the recognition site allows for customization of the overhangs generated. The MoClo system is hierarchical. First, basic parts (promoters, UTRs, CDS and terminators) are assembled in level 0 plasmids in the kit. In a single reaction, the individual parts can be assembled into vectors containing transcriptional units (level 1). Furthermore, MoClo allows for directional assembly of multiple transcriptional units. Successful assembly of constructs using MoClo can be confirmed by visual readouts (blue/white or red/white screening). For the protocol, you can find it here.


Note: The basic parts sequences of the Sci-Phi 29 collection in the registry contain only the part sequence and therefore contain no overhangs or restriction sites. For synthesizing MoClo compatible parts, refer to table 2.


Table 1: Overview of different level in MoClo

Level Basic/Composite Type Enzyme
Level 0 Basic Promoters, 5’ UTR, CDS and terminators BpiI
Level 1 Composite Transcriptional units BsaI
Level 2/M/P Composite Multiple transcriptional units BpiI

For synthesizing basic parts, the part of interest should be flanked by a BpiI site and its specific type overhang. These parts can then be cloned into the respective level 0 MoClo parts. For level 1, where individual transcriptional units are cloned, the overhangs come from the backbone you choose. The restriction sites for level 1 are BsaI. However, any type IIS restriction enzyme could be used.


Table 2: Type specific overhangs and backbones for MoClo. Green indicates the restriction enzyme recognition site. Blue indicates the specific overhangs for the basic parts

Basic Part Sequence 5' End Sequence 3' End Level 0 backbone
Promoter NNNN GAAGAC NN GGAG TACT NN GTCTTC NNNN pICH41233
5’ UTR NNNN GAAGAC NN TACT AATG NN GTCTTC NNNN pICH41246
CDS NNNN GAAGAC NN AATG GCTT NN GTCTTC NNNN pICH41308
Terminator NNNN GAAGAC NN GCTT CGCT NN GTCTTC NNNN pICH41276

Characterization

According to our model, the genetic implementation of the iFFL system yields the same gene of interest (GOI) expression levels when the transcriptional rate of both genes (TALE and GOI) are changed in the same ratio as can be seen in Figure 3.

  • Figure 3: Steady-state GFP production while transcriptional rates of both TALE and GOI are changed. The lines indicate constant ratio of transcriptional rates

For the system to be versatile, it is important to achieve different levels of output gene expression (GFP). Hence, in the optimized iFFL system the TALE repressor is expressed by a higher strength promoter compared to the promoter controlling GFP expression.

To validate the insulation of the gene expression (GFP) in the iFFL system to changes in transcriptional rates, GFP fluorescence was measured at different IPTG concentrations by flow cytometry at log-phase of growth. Change in IPTG concentrations, changes in vivo concentrations of T7 RNAP and this contributes to variations in transcriptional rates. In unrepressed systems, the expression of the GOI is a function of IPTG concentrations. However, in iFFL systems due to the expression of TALE repressor, similar GFP expression across different IPTG concentrations is expected.

The iFFL system was validated by measuring GFP using flow cytometry. As a control, GFP under the control of T7sp1 promoter was used. As a reference for background fluorescence, E. coli BL21(DE3) cells without plasmids were used. The protocol for sample preparation can be found here.

Scatter plots (Figures 7 and 8) for the unprepressed control and T7 based optimized iFFL were gated by eye to select for the most dense regions. Figures 4 and 5 show fluorescence measurements for the gated populations of the unrepressed control and optimized iFFL system at different IPTG concentrations respectively.

  • Figure 4: Fluorescence measurements from gated population of unrepressed control (for scatter plot refer Figure 7) at different IPTG concentrations. Black: E. coli BL21(DE3)(Green: 0mM, Red: 0.1mM, Blue: 0.5mM and Purple: 1mM
  • Figure 5: Fluorescence measurements from gated population of optimized iFFL system (for scatter plot refer Figure 8) at different IPTG concentrations. Black: E. coli BL21(DE3), Green: 0mM, Red:0.1mM, Blue: 0.5mM and Purple: 1mM

In Figure 4, it is seen that GFP fluorescence of the unrepressed control changes with IPTG concentrations. However,(in Figure 5) for the optimized iFFL system, the GFP fluorescence curves for all the IPTG concentrations overlap and therefore is independent of IPTG concentrations.

  • Figure 6: Steady state GFP fluorescnece measurements using flow cytometry at different IPTG concentrations. Measurements were made at log-phase of growth and the median fluorescence of the gated populations is plotted.

From Figure 6, it is seen that despite changes in IPTG the GFP fluorescence remains the same while the GFP fluorescence of the control increases with IPTG concentrations. This suggests that the gene of interest expression is independent of in-vivo T7 RNAP concentrations (IPTG concentrations) thereby independent of changes in transcriptional rate.

Conclusion

The characterization of the T7 based optimized iFFL system suggests that the circuit is robust to changes in transcriptional rates.


Raw Data

  • Figure 8: Scatter plot for unrepressed control (forward scatter vs side scatter)
  • Figure 9: Scatter plot for T7 based optimized iFFL system (forward scatter vs side scatter)

References