Difference between revisions of "Team:Technion Israel/Tar improvements"

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<br>
 
<br>
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >Swarming assay</a> was conducted  
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >Swarming assay</a> was conducted  
with strains that express the Tar chemoreceptor with both RBS and native RBS, respectively (Fig. 1 and Fig. 2). Both exhibited chemotactic response and motility compared to the  
+
with strains that express the Tar chemoreceptor with both RBS and native RBS, respectively (Fig. 6 and Fig. 7). Both exhibited chemotactic response and motility compared to the  
 
negative and positive control. Moreover, these results show a difference in radius size between the RBS  
 
negative and positive control. Moreover, these results show a difference in radius size between the RBS  
and the native RBS (Fig. 3). The larger radius of the native RBS suggests a higher sensitivity of the chemotaxis  
+
and the native RBS (Fig. 8). The larger radius of the native RBS suggests a higher sensitivity of the chemotaxis  
 
system, due to a higher expression of Tar <b>(1)</b>.
 
system, due to a higher expression of Tar <b>(1)</b>.
 
</p>
 
</p>
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Attractant response of the Tar receptor tested using  
 
Attractant response of the Tar receptor tested using  
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >chip microscope assay</a>.  
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >chip microscope assay</a>.  
The strain expressing Tar, is moving toward high concentration of aspartate. As indicated (Fig. 4), after  
+
The strain expressing Tar, is moving toward high concentration of aspartate. As indicated (Fig. 9), after  
15 minutes, the number of the bacteria in the frame increased compared to the control (Fig. 5) bacteria which  
+
15 minutes, the number of the bacteria in the frame increased compared to the control (Fig. 10) bacteria which  
 
remained approximately unchanged.
 
remained approximately unchanged.
 
</p>
 
</p>
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<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >chip color assay</a>.  
 
<a href="https://2016.igem.org/Team:Technion_Israel/Experiments" >chip color assay</a>.  
 
The strain expressing Tar, is moving away from the high concentration of Co<sup>+2</sup>. As can  
 
The strain expressing Tar, is moving away from the high concentration of Co<sup>+2</sup>. As can  
be seen (Fig. 6 a) after 15 minutes, the colored bacteria formed a cluster which is visible to  
+
be seen (Fig. 11 a) after 15 minutes, the colored bacteria formed a cluster which is visible to  
the naked eye, whereas the control bacteria (Fig. 6 b) did not form a cluster.
+
the naked eye, whereas the control bacteria (Fig. 11 b) did not form a cluster.
 
</p>
 
</p>
 
 

Revision as of 12:55, 19 October 2016

S.tar, by iGEM Technion 2016

S.tar, by iGEM Technion 2016

Introduction

We chose Tar (Taxis Aspartate Receptor of E. coli as the template chemoreceptor to engineer the chimeric chemoreceptor. To do that, we first need to characterize Tar in terms of location in vivo and its function, mainly the response and movement of bacteria. In order to do so, the plasmid expressing Tar was cloned to chemoreceptorless E.coli strain UU1250. A proper characterization of the bacteria will serve as a good reference for indicating that our newly designed chemoreceptors are functional.

Fig. 1: Scheme of Tar chemoreceptor.

Expression


Studies have shown that overexpression of a single chemoreceptor increases the sensitivity of the bacteria to the chemoreceptor's ligands (1). Due to this property we constructed a high expression system of Tar chemoreceptor, based on the K777000 BioBrick. This expression system includes the strongest Anderson promoter (J23100), the strongest RBS (B0034), according to Warsaw 2010's measurement, the Tar encoding sequence (K777000) and a double terminator (B0015).
This plasmid, K1992004, was then transformed into UU1250 strain to generate UST strain. This new strain is assumed to have high expression of single chemoreceptor, due to the strong promoter and strong RBS (Fig. 2).

Fig. 2: K1992004 - High expression biological circuit ; J23100 promoter, B0034 RBS, K777000 Tar chemoreceptor and terminator.




In order to explore the Tar chemoreceptor as it is in nature, we also decided to examine the effect of native RBS, as found in E. coli, on chemotaxis system. The strong RBS (referred as RBS) was replaced by the native RBS (referred as nRBS) of Tar as found in the E.coli genome (Fig. 3). The new expression system K1992005 differs only by the RBS, allowing the comparison between the two RBSs.
The two strains, which differ in the RBS (RBS vs. nRBS) were examined with swarming assay, in which the chemotaxis ability is examined in a swarm plate. The bacteria depleting the attractant and move outwards, creating a halo. You can view the results in the movement section (Fig. 8). The results were quite surprising. The strain with native RBS had a better chemotaxis ability, than the strain that contain strong RBS. This finding suggests a higher expression of Tar, means the native RBS might be "stronger" than the strong RBS, according to Warsaw 2010's measurement.

Fig. 3: K1992005 - High expression circuit using the Tar native RBS.

Location

E.coli native chemoreceptors cluster in the cell poles. This property is critical for signal amplification and adaptation of the cell, since it crucial for additional proteins, such as kinases and adaptors to interact with the chemoreceptor, once it migrated to its proper location in the membrane (for profound information on chemotaxis system, click here. Although little is known about the mechanism of localization, it is important to retain this property with our newly designed receptors - to ensure a functional and a sensitive chemotaxis response (2).

GFP labeling is a very common technique to examine the migration and localization of proteins in vivo . Fusion of GFP (E0040) to the Tar chemoreceptor enabled us to track the migration and localization of the Tar-GFP fusion protein to the cell poles. The fusion was conducted using a flexible linker (J18921), in order to preserve the three-dimensional structures of the receptor-proteins. The Tar-GFP (K1992003) was expressed using the two expression systems (K1992008 and K1992009), and localization was examined using an inverted fluorescence microscope (Fig. 4 and Fig. 5). In both cases, high concentration of fluorescence can be detected in the cell poles, indicating a proper migration and localization of the Tar receptor. Comparison between the two expression systems (strong RBS and native RBS) did not show any significant difference. This finding is consistent with the movement experiments results, which indicate that both strains (with RBS & nRBS) contain an active Tar.




Fig. 4: Tar-GFP fusion results: A. Positive control - E.Coli strain expressing GFP protein. B. Negative control - UU1250 strain expressing Tar chemoreceptor. C. Tar-GFP expressed using B0034 RBS. D. Tar-GFP expressed using the native RBS (488nm wavelength).


Fig. 5: Alignment of Tar-GFP white light and 488nm wavelength results: A. Positive control- E.Coli strain expressing GFP protein, B. Negative control- UU1250 strain expressing Tar chemoreceptor, C. Tar-GFP expressed using B0034 RBS, D. Tar-GFP expressed using the native RBS.


Response and movement

Tar exhibits attraction response toward aspartate and a repellent response away from Ni+2 and Co+2 concentrations (3). Various chemotaxis assays were performed, using those substances, to show the bacteria's response and movement. In turn, these results were used as a reference, in order to test the bacterial behavior with our designed chemoreceptors.

Swarming assay was conducted with strains that express the Tar chemoreceptor with both RBS and native RBS, respectively (Fig. 6 and Fig. 7). Both exhibited chemotactic response and motility compared to the negative and positive control. Moreover, these results show a difference in radius size between the RBS and the native RBS (Fig. 8). The larger radius of the native RBS suggests a higher sensitivity of the chemotaxis system, due to a higher expression of Tar (1).




Fig. 6: (a) Tar expression in UU1250 strain, resulting a halo indicating a functional chemotaxis response. (b) Negative control- UU1250 strain w/o the Tar expression plasmid. (c) positive control - ΔZ strain expressing all chemoreceptors.


Fig. 7: (a) Tar expression using the native RBS in UU1250 strain, resulting a halo indicating a functional chemotaxis response. (b) Negative control- UU1250 strain w/o the Tar expression plasmid. (c) positive control - ΔZ strain expressing all chemoreceptors.


Fig. 8: Comparsion between Tar expression using the strong RBS and native RBS in UU1250 strain: (a) Tar expression in UU1250 strain cloned with K1992004 expretion system - strong RBS. (b) Tar expression in UU1250 strain cloned with K1992004 expretion system - Tar native RBS




Attractant response of the Tar receptor tested using chip microscope assay. The strain expressing Tar, is moving toward high concentration of aspartate. As indicated (Fig. 9), after 15 minutes, the number of the bacteria in the frame increased compared to the control (Fig. 10) bacteria which remained approximately unchanged.




a.

b.

Fig. 9: (a) cells expressing Tar w aspartate t=0 (b) cells expressing Tar w aspartate t=15 min




a.

b.

Fig. 10: (a) cells expressing Tar w motility buffer t=0 (b) cells expressing Tar w motility buffer t=15 min




Repellent response of Tar receptor tested using chip color assay. The strain expressing Tar, is moving away from the high concentration of Co+2. As can be seen (Fig. 11 a) after 15 minutes, the colored bacteria formed a cluster which is visible to the naked eye, whereas the control bacteria (Fig. 11 b) did not form a cluster.

a.

b.

Fig. 11: Chemotaxis test on the Chip for Tar UU1250 strain expressing Tar chemoreceptor and Chromoprotein: (a) Repellent added (b) Control- motility buffer.




References:
1. SOURJIK, Victor; BERG, Howard C. Functional interactions between receptors in bacterial chemotaxis. Nature, 2004, 428.6981: 437-441.‏

2. SHIOMI, Daisuke, et al. Helical distribution of the bacterial chemoreceptor via colocalization with the Sec protein translocation machinery. Molecular microbiology, 2006, 60.4: 894-906.‏

3. BI, Shuangyu; LAI, Luhua. Bacterial chemoreceptors and chemoeffectors.Cellular and Molecular Life Sciences, 2015, 72.4: 691-708.‏




S.tar, by iGEM Technion 2016