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Team:UT-Tokyo/Project/Results
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===1.1. The production of L-Asp=== | ===1.1. The production of L-Asp=== | ||
| - | [[Image:Ut_tokyo_AspA_react.png|400px|thumb|<font color="black">AspA | + | [[Image:Ut_tokyo_AspA_react.png|400px|thumb|<font color="black">AspA synthesizes L-Asp from fumaric acid and ammonia</font>]] |
:In the past studies aiming at L-Asp over-production, the amount of L-Asp was determined by HPLC [1,2]. However, having no available HPLC-apparaturs, we were unable to use this method, so we tried to detect it in alternative ways. | :In the past studies aiming at L-Asp over-production, the amount of L-Asp was determined by HPLC [1,2]. However, having no available HPLC-apparaturs, we were unable to use this method, so we tried to detect it in alternative ways. | ||
| - | :We first tried to make an ''E. coli'' producing L-Asp using lac promoter BBa_R0011. WT transformed with [[Team:UT-Tokyo/Parts|BBa_K518004]](lacP-RBS-AspA-d.Ter) was pre-cultured with 1mM IPTG. The culture was soaked in the fumaric acid solution containing annmonia. Note that AspA | + | :We first tried to make an ''E. coli'' producing L-Asp using lac promoter BBa_R0011. WT transformed with [[Team:UT-Tokyo/Parts|BBa_K518004]](lacP-RBS-AspA-d.Ter) was pre-cultured with 1mM IPTG. The culture was soaked in the fumaric acid solution containing annmonia. Note that AspA synthesizes L-Asp from fumaric acid and ammonia. The reaction mix was incubated at 37 degreed celcius for 1 hour. After the incubation, the concentration of L-Asp was measured through ninhydrin staining and ultraviolet-visible spectroscopy. Unfortunatelly, we could not gain obvious data. We had ninhydrin react with L-Asp produced by AspA. Ninhydrin probably reacted not only with L-Asp but also with remaining ammonia. |
:The second attempt was TLC. Two microlitters of the supernatant of the incubated reaction solution was spotted onto a TLC sillica plate, and extracted with 70% ethanol. We had expected L-Asp and ammonia to be separated. However, it was impracible to separate them using ethanol. We then tried various concentrations of acetone as a developing solvent, only to observe smearing lanes. | :The second attempt was TLC. Two microlitters of the supernatant of the incubated reaction solution was spotted onto a TLC sillica plate, and extracted with 70% ethanol. We had expected L-Asp and ammonia to be separated. However, it was impracible to separate them using ethanol. We then tried various concentrations of acetone as a developing solvent, only to observe smearing lanes. | ||
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===1.2. The characterization of L-Asp chemotaxis=== | ===1.2. The characterization of L-Asp chemotaxis=== | ||
:Next, to show that ''E. coli'' moves in the direction of higher L-Asp concentration, we carried out swarming assays. WT colony was innoculated into 0.25% agar LB plate and L-Asp solution was instilled. Plates were left at room temperture. After further 20 hours, those plates were captured. The representative photograph of a swarming colony is shown in Fig. 1A. | :Next, to show that ''E. coli'' moves in the direction of higher L-Asp concentration, we carried out swarming assays. WT colony was innoculated into 0.25% agar LB plate and L-Asp solution was instilled. Plates were left at room temperture. After further 20 hours, those plates were captured. The representative photograph of a swarming colony is shown in Fig. 1A. | ||
| + | :To determine the movement of colonies toward the location of L-Asp instillation, we then performed an image analsis. Obtained images were undergone a computational processing to find an edge of the colonies. The processed image is shown in Fig. 1B. | ||
| + | <html><center> | ||
| + | <img src="https://static.igem.org/mediawiki/2011/b/bf/Ut_assay_asp_taxis.png" align="center" width = "300"><br> | ||
| + | Fig. 1A: A swarming colony after 20-hour incubating | ||
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| + | <img src="https://static.igem.org/mediawiki/2011/3/33/Ut_Asp%28-%29_65h_3.png" align="center" width = "300"><br> | ||
| + | Fig. 1B: A colony image precessed to find the edge. | ||
| + | <!--fig.1B--> | ||
| + | </center></html> | ||
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:In this assay, we defined a colony movement as a vector from the center of a colony to the intial tip position. The colony movements were presented in Fig. 1C. The migration length of colonies was measured about 38(±9) mm with L-Asp solution, while 13(±6) mm without L-Asp. The results clearly show that colonies exposed to the L-Asp solution swarmed significantly, compared to colonies of the control group. Data is obtained from more than 6 experiment. | :In this assay, we defined a colony movement as a vector from the center of a colony to the intial tip position. The colony movements were presented in Fig. 1C. The migration length of colonies was measured about 38(±9) mm with L-Asp solution, while 13(±6) mm without L-Asp. The results clearly show that colonies exposed to the L-Asp solution swarmed significantly, compared to colonies of the control group. Data is obtained from more than 6 experiment. | ||
Revision as of 04:56, 5 October 2011
Project
iGEM UT-Tokyo
Results
- This page is composed of the results of our experiments.
- The experiments are to evaluate the possibility and potential of our idea and can be divided into two sections: chemoattraction and production of L-Asp, and motility regulation by CheZ. Each page of the two sections includes the goal and methodological outline of experiments carried out as well as the results.
- In addition, we deviced “dual luciferase assay kit” in order to establish better measurement of gene expression. This kit is designed so that luciferase assay can easily be conducted for iGEM-standardized promoters. Explanation and analysis of this kit is given here.
- Details of methods and experimental conditions for each experiment are provided in Method page
Section 1: Substrate-induced Cell Assembling
1. Summary
- Bacteria including Escherichia coli has a property known as chemotaxis. They are believed to be attracted toward certain substances, including L-aspartate (L-Asp). We have tryed to make an E. coli attracting other bacteria toward itself by a substrate-stimulated L-Asp production. Also, we characterized the chemoattraction of E. coli toward L-Asp, and compared the results to a computational simulation. We obtained supportive evidences for the agreement of the wet and the dry. Therefore, we propose that, if we get an E. coli secreting enough level of L-Asp, we can devise an inducible cell mustering system.
1.1. The production of L-Asp
- In the past studies aiming at L-Asp over-production, the amount of L-Asp was determined by HPLC [1,2]. However, having no available HPLC-apparaturs, we were unable to use this method, so we tried to detect it in alternative ways.
- We first tried to make an E. coli producing L-Asp using lac promoter BBa_R0011. WT transformed with BBa_K518004(lacP-RBS-AspA-d.Ter) was pre-cultured with 1mM IPTG. The culture was soaked in the fumaric acid solution containing annmonia. Note that AspA synthesizes L-Asp from fumaric acid and ammonia. The reaction mix was incubated at 37 degreed celcius for 1 hour. After the incubation, the concentration of L-Asp was measured through ninhydrin staining and ultraviolet-visible spectroscopy. Unfortunatelly, we could not gain obvious data. We had ninhydrin react with L-Asp produced by AspA. Ninhydrin probably reacted not only with L-Asp but also with remaining ammonia.
- The second attempt was TLC. Two microlitters of the supernatant of the incubated reaction solution was spotted onto a TLC sillica plate, and extracted with 70% ethanol. We had expected L-Asp and ammonia to be separated. However, it was impracible to separate them using ethanol. We then tried various concentrations of acetone as a developing solvent, only to observe smearing lanes.
- One of the main reasons of the failure is that our methods relied on ninhydrin reaction. Ninhydrin certaionly reacts with L-Asp. However, ninhydrin also reacts with an indispensable substance to AspA reaction. We should have selected a way that only one of reactants and products can be detected definitely. Now then, the sequencing result shows that Assembling BBa_K518004 was success. So, it may be possible to make sure of the work if a right method is selected. For example, L-Asp is detected by HTLC and AspA protain is detected instead of L-Asp.
1.2. The characterization of L-Asp chemotaxis
- Next, to show that E. coli moves in the direction of higher L-Asp concentration, we carried out swarming assays. WT colony was innoculated into 0.25% agar LB plate and L-Asp solution was instilled. Plates were left at room temperture. After further 20 hours, those plates were captured. The representative photograph of a swarming colony is shown in Fig. 1A.
- To determine the movement of colonies toward the location of L-Asp instillation, we then performed an image analsis. Obtained images were undergone a computational processing to find an edge of the colonies. The processed image is shown in Fig. 1B.
Fig. 1A: A swarming colony after 20-hour incubating
Fig. 1B: A colony image precessed to find the edge.
- In this assay, we defined a colony movement as a vector from the center of a colony to the intial tip position. The colony movements were presented in Fig. 1C. The migration length of colonies was measured about 38(±9) mm with L-Asp solution, while 13(±6) mm without L-Asp. The results clearly show that colonies exposed to the L-Asp solution swarmed significantly, compared to colonies of the control group. Data is obtained from more than 6 experiment.
- -Reference-
- [1]. Chao, Y. P., Lai, Z. J., Chen, P., & Chern, J. T. (1999). Enhanced conversion rate of L-phenylalanine by coupling reactions of aminotransferases and phosphoenolpyruvate carboxykinase in Escherichia coli K-12. Biotechnol Prog, 15(3), 453-458.
- [2]. Chao, Y., Lo, T., & Luo, N. (2000). Selective production of L-aspartic acid and L-phenylalanine by coupling reactions of aspartase and aminotransferase in Escherichia coli. Enzyme Microb Technol, 27(1-2), 19-25.
Section 2
TBD
Section 3
TBD
