Difference between revisions of "Part:BBa K3989003"
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[[File:21_UZurich_AHL_sensitivity.jpeg|700px|]] | [[File:21_UZurich_AHL_sensitivity.jpeg|700px|]] | ||
− | <b>Figure 1.</b> AHL-sensitivity of EsaR and its variant of promoter P<sub> | + | |
+ | <b>Figure 1.</b> AHL-sensitivity of EsaR and its variant of promoter P<sub>esaS</sub>. Different AHL concentrations are used: 0, 1nM, 10nM, 100nM, 1000nM and 10000nM.[1] | ||
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In the P<sub>esa</sub> promoter controlled Quorum Sensing system, EsaR acts as a regulator that can bind to a specific site of the promoter P<sub>esa</sub>. Depending on the different types of the P<sub>esa</sub>(P<sub>esaR</sub> and P<sub>esaS</sub>), EsaR can be either a repressor(for P<sub>esaR</sub>) or an activator(for P<sub>esaR</sub>). The detailed mechanism is shown below: | In the P<sub>esa</sub> promoter controlled Quorum Sensing system, EsaR acts as a regulator that can bind to a specific site of the promoter P<sub>esa</sub>. Depending on the different types of the P<sub>esa</sub>(P<sub>esaR</sub> and P<sub>esaS</sub>), EsaR can be either a repressor(for P<sub>esaR</sub>) or an activator(for P<sub>esaR</sub>). The detailed mechanism is shown below: | ||
− | < | + | </html> |
− | + | ||
− | + | [[File:21_UZurich_EsaR_activation_repression.jpeg|700px|]] | |
− | < | + | |
+ | <b>Figure 2.</b> EsaR acts as either an activator or a repressor.[1] | ||
+ | |||
+ | <html> | ||
From the figure we can see that, the EsaR protein binds to a specific site called the <i>esa box</i>. This binding site has a different location on P<sub>esaR</sub> and P<sub>esaS</sub> and the EsaR binds to it when there is no AHL | From the figure we can see that, the EsaR protein binds to a specific site called the <i>esa box</i>. This binding site has a different location on P<sub>esaR</sub> and P<sub>esaS</sub> and the EsaR binds to it when there is no AHL | ||
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− | In our project, we performed a characterisation specifically to the wild-type, variant D91G, V220A and I70V. The strategy we used is to express a GFP in a plasmid(detail of the construct: <a href="https://parts.igem.org/Part:BBa_K3989025"> BBa_K3989025</a>) using promoter P<sub> | + | In our project, we performed a characterisation specifically to the wild-type, variant D91G, V220A and I70V. The strategy we used is to express a GFP in a plasmid(detail of the construct: <a href="https://parts.igem.org/Part:BBa_K3989025"> BBa_K3989025</a>) using promoter P<sub>esaS</sub>. The AHL molecule's concentration are same as people used in the literature[1]. |
− | We used plate reader and flow cytometry to analyse the fluorescence generated by GFP, the | + | We used plate reader and flow cytometry to analyse the fluorescence generated by GFP, the results are shown in figure 3 and 4. |
− | < | + | </html> |
− | + | ||
− | + | [[File:21_UZurich_characterisation_plate_reader.jpeg|700px|]] | |
− | < | + | |
+ | <b>Figure 3.</b> Fluorescence intensity measurement by plate reader(96-well plate). The measurements were done every one hour and this is the curve of the last test. | ||
+ | |||
+ | <html> | ||
From the plate reader result, it is clear that we reproduce the response trend of these variants: D91G and V220A are more sensitive and I70V shows a similar sensitivity compared to wild-type. D91G variant cells shows almost no fluorescence when the AHL concentration is 100nM, where other variants or wild-type are just start to have a lower GFP expression level. However, the initial gene expression level controlled by these systems are not reproducible. D91G and V220A show a lower expression level and I70V is much higher than what we expected. | From the plate reader result, it is clear that we reproduce the response trend of these variants: D91G and V220A are more sensitive and I70V shows a similar sensitivity compared to wild-type. D91G variant cells shows almost no fluorescence when the AHL concentration is 100nM, where other variants or wild-type are just start to have a lower GFP expression level. However, the initial gene expression level controlled by these systems are not reproducible. D91G and V220A show a lower expression level and I70V is much higher than what we expected. | ||
− | < | + | </html> |
− | + | ||
− | + | [[File:21_UZurich_characterisation_facs.png|700px|]] | |
− | < | + | |
+ | <b>Figure 4.</b> Fluorescence intensity measurement by flow cytometry. The samples are taken from the plate, in which the bacteria has been cultured for 7 hours. | ||
+ | |||
+ | <html> | ||
In this figure, we mainly show the distribution of the bacterium cells with a different fluorescence intensity. And it shows that except for I70V, other variants and wild-type have the same performance compared to our plate reader analysis. In I70V sample, the cell population is concentrated at a very low fluorescence intensity level and only few of the cells show a high intensity. After increasing the AHL concentration to 100nM, the population that have a high fluorescence intensity shift back to normal and when the concentration raises up to 1000nM, we can barely see any cells with high intensity. This performance might be caused by the quality of our sample because even there is no AHL molecule, there are only a few of cells show a high fluorescence intensity. Further reproduce experiment need to be performed. | In this figure, we mainly show the distribution of the bacterium cells with a different fluorescence intensity. And it shows that except for I70V, other variants and wild-type have the same performance compared to our plate reader analysis. In I70V sample, the cell population is concentrated at a very low fluorescence intensity level and only few of the cells show a high intensity. After increasing the AHL concentration to 100nM, the population that have a high fluorescence intensity shift back to normal and when the concentration raises up to 1000nM, we can barely see any cells with high intensity. This performance might be caused by the quality of our sample because even there is no AHL molecule, there are only a few of cells show a high fluorescence intensity. Further reproduce experiment need to be performed. | ||
</html> | </html> | ||
+ | ==Structural information contribution made by iGEM23_SDU-CHINA== | ||
+ | Written by Suiru Lu and Xiaoting Wang | ||
+ | ===Summary=== | ||
+ | In the EsaI/R Quorum Sensing (QS) system, the interaction between EsaR protein and AHL (3OC6HSL) directly influences the sensitivity of the promoter to AHL, thereby determining the response timing of the QS switch. For enhanced precision control, we introduced <strong>19 point mutations </strong> (more detail can be found on our wiki)in EsaR and predicted the subsequent three-dimensional structures using the <strong>AlphaFold2</strong> algorithm. Using 3 online tools, we assessed the quality of our model. Also, a comprehensive quantitative analysis of binding affinity was conducted using the <strong> AutoDock</strong>software. Here, we add structural information for EsaR170V. | ||
+ | ===3D structure of EsaR 170V=== | ||
+ | |||
+ | <html> | ||
+ | <figure> | ||
+ | <img src="https://static.igem.wiki/teams/4583/wiki/170v-3.png"width="630" height="400"> | ||
+ | <figcaption><b>Fig. 1 </b>. 3D structure of EsaR170V </figcaption> | ||
+ | </figure> | ||
+ | </html> | ||
+ | ===The interaction between EsaR170V and AHL=== | ||
+ | * The binding energy with AHL is -7.5 kcal/mol. | ||
+ | <html> | ||
+ | <figure> | ||
+ | <img src="https://static.igem.wiki/teams/4583/wiki/170v-1.png"width="630" height="400"> | ||
+ | <figcaption><b>Fig. 2</b>. The results of the docking between EsaR and AHL molecules. </figcaption> | ||
+ | </figure> | ||
+ | </html> | ||
+ | |||
+ | <html> | ||
+ | <figure> | ||
+ | <img src="https://static.igem.wiki/teams/4583/wiki/170v-2.png"width="520" height="300"> | ||
+ | <figcaption><b>Fig. 3 </b>. The results of the docking between EsaR and AHL molecules. </figcaption> | ||
+ | </figure> | ||
+ | </html> | ||
+ | ===Conclusion=== | ||
+ | Based on the information we provided, future iGEM teams can select appropriate mutants to obtain QS systems with different strengths. | ||
===Sequence and Features=== | ===Sequence and Features=== | ||
<partinfo>BBa_K3989003 SequenceAndFeatures</partinfo> | <partinfo>BBa_K3989003 SequenceAndFeatures</partinfo> |
Latest revision as of 08:26, 9 October 2023
EsaR I70V variant
A variant of the Quorum Sensing regulator protein EsaR BBa_K2116001 with an isoleucine substituted by valine.
Basic information
EsaR BBa_K2116001 is a regulator protein which regulates the promoter of a bacterial Quorum Sensing system. By interacting with the Quorum Sensing molecules(a class of molecules called AHL. In our project, we use 3OC6HSL since it shows a higher sensitivity.), it can either act as a repressor or an activator depending on the location of the promoter it binds. Besides this wild-type, there are some other variants in which one or more amino acids residues are substituted. Consequently, the sensitivity of these variants to 3OC6HSL are different. There are mainly four variants except the wild-type EsaR: EsaR-D91G( BBa_K3989004 ), EsaR-V220A( BBa_K3989005 ), EsaR-I70V(this part) and EsaR-I70V/V220A. From previous studies, both the variant D91G and V220A show a higher sensitivity to 3OC6HSL compared to the wild-type and the I70V variant shows a similar sensitivity but a lower gene expression level.(See figure 1)
Figure 1. AHL-sensitivity of EsaR and its variant of promoter PesaS. Different AHL concentrations are used: 0, 1nM, 10nM, 100nM, 1000nM and 10000nM.[1]
How it works
In the Pesa promoter controlled Quorum Sensing system, EsaR acts as a regulator that can bind to a specific site of the promoter Pesa. Depending on the different types of the Pesa(PesaR and PesaS), EsaR can be either a repressor(for PesaR) or an activator(for PesaR). The detailed mechanism is shown below:
Figure 2. EsaR acts as either an activator or a repressor.[1]
From the figure we can see that, the EsaR protein binds to a specific site called the esa box. This binding site has a different location on PesaR and PesaS and the EsaR binds to it when there is no AHL molecules exist. However, when interacting with AHL, the EsaR will perform an allocation change. Subsequently, it will dislocate from the binding site and will either recruit or interfere the RNA polymerase for the transcription.
Characterisation
In our project, we performed a characterisation specifically to the wild-type, variant D91G, V220A and I70V. The strategy we used is to express a GFP in a plasmid(detail of the construct: BBa_K3989025) using promoter PesaS. The AHL molecule's concentration are same as people used in the literature[1]. We used plate reader and flow cytometry to analyse the fluorescence generated by GFP, the results are shown in figure 3 and 4.
Figure 3. Fluorescence intensity measurement by plate reader(96-well plate). The measurements were done every one hour and this is the curve of the last test.
From the plate reader result, it is clear that we reproduce the response trend of these variants: D91G and V220A are more sensitive and I70V shows a similar sensitivity compared to wild-type. D91G variant cells shows almost no fluorescence when the AHL concentration is 100nM, where other variants or wild-type are just start to have a lower GFP expression level. However, the initial gene expression level controlled by these systems are not reproducible. D91G and V220A show a lower expression level and I70V is much higher than what we expected.
Figure 4. Fluorescence intensity measurement by flow cytometry. The samples are taken from the plate, in which the bacteria has been cultured for 7 hours.
In this figure, we mainly show the distribution of the bacterium cells with a different fluorescence intensity. And it shows that except for I70V, other variants and wild-type have the same performance compared to our plate reader analysis. In I70V sample, the cell population is concentrated at a very low fluorescence intensity level and only few of the cells show a high intensity. After increasing the AHL concentration to 100nM, the population that have a high fluorescence intensity shift back to normal and when the concentration raises up to 1000nM, we can barely see any cells with high intensity. This performance might be caused by the quality of our sample because even there is no AHL molecule, there are only a few of cells show a high fluorescence intensity. Further reproduce experiment need to be performed.
Structural information contribution made by iGEM23_SDU-CHINA
Written by Suiru Lu and Xiaoting Wang
Summary
In the EsaI/R Quorum Sensing (QS) system, the interaction between EsaR protein and AHL (3OC6HSL) directly influences the sensitivity of the promoter to AHL, thereby determining the response timing of the QS switch. For enhanced precision control, we introduced 19 point mutations (more detail can be found on our wiki)in EsaR and predicted the subsequent three-dimensional structures using the AlphaFold2 algorithm. Using 3 online tools, we assessed the quality of our model. Also, a comprehensive quantitative analysis of binding affinity was conducted using the AutoDocksoftware. Here, we add structural information for EsaR170V.
3D structure of EsaR 170V
The interaction between EsaR170V and AHL
- The binding energy with AHL is -7.5 kcal/mol.
Conclusion
Based on the information we provided, future iGEM teams can select appropriate mutants to obtain QS systems with different strengths.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
References
1) Shong, J., Huang, Y. M., Bystroff, C., & Collins, C. H. (2013). Directed evolution of the quorum-sensing regulator EsaR for increased signal sensitivity. ACS chemical biology, 8(4), 789-795.