Team:Tokyo Tech/Project/Artificial Cooperation System
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'''I, characterization of R0061 (promoter repressed by LuxR/3OC6HSL)'''<br> | '''I, characterization of R0061 (promoter repressed by LuxR/3OC6HSL)'''<br> | ||
===Introduction=== | ===Introduction=== | ||
- | We characterized luxR repression promoter. In the Artificial Cooperation System, we inserted chloramphenicol resistance coding sequence | + | We characterized luxR repression promoter. In the Artificial Cooperation System, we inserted chloramphenicol resistance coding sequence into this promoter. Thus, this promoter plays an important role in Artificial Cooperation System. We wanted to characterize the strength of this promoter which has never been done before in BioBrick in order to design new promoter based on this data. |
First, we confirmed R0061, which is a existing BioBrick promoter repressed by LuxR/3OC6HSL complex. To confirm this promoter, we constructed following two plasmids (fig〇〇and fig〇〇) | First, we confirmed R0061, which is a existing BioBrick promoter repressed by LuxR/3OC6HSL complex. To confirm this promoter, we constructed following two plasmids (fig〇〇and fig〇〇) | ||
Revision as of 02:35, 26 October 2010
Contents |
Artificial Cooperation System
Highlight
・We designed Artificial Cooperation System to endow E.coli with humanity.
・We constructed two NEW BioBricks, LuxR repression promoter and chloramphenicol resistance gene connected to the LuxR activation promoter.
・We characterized the existing parts R0061, LuxR repression promoter, and R0062, LuxR activation promoter.
・We characterized the existing part K092400, rbs-luxI-ter.
Requirement
In order to make our system, we need introduce cell-to-cell communication mechanism. Many cell-to-cell communication mechanisms in bacteria are known, though the mechanisms of many systems are not well-understood yet. Thus we used “quorum sensing” whose mechanism is well studied. And quorum sensing is popular in synthetic biology and iGEM.
quorum sensing
Quorum Sensing (QS) refers to cell-to-cell communication systems that are used by many microorganisms to sense their local cell densities. This sensing mechanism is based on the production, secretion and detection of small signaling molecules, whose concentration correlates to the abundance of secreting microorganisms in the vicinity. When the signal concentration reaches a threshold, they know the ‘quorum’ is formed, and the communicating microorganisms undergo a coordinated change in their gene-expression profiles. As a result, they initiate complicated activities which would not have been occurred at smaller cell numbers. Secretion of virulence factors, initiation of biofilm formation, sporulation, competence, mating, root nodulation, bioluminescence, and production of secondary metabolites are the examples for the activities mentioned above.
There are two regulatory genes involved in QS, I and R genes. The I gene produces I protein and directs the synthesis of an N-acyl homoserine lactone (AHL). AHL is bacteria-specific and gene-specific signal molecule. On the other hand, R protein, which is expressed by R gene, binds to the synthesized AHL signal molecule. The AHL and R protein complex acts as a transcription factor.
In synthetic biology field or iGEM, lux, las, and rhl have been used frequently.lux, lasI and rhlI gene synthesize N-(3-oxohexanoyl) homoserine lactone(3OC6HSL), 3-oxododecanoyl- homoserine lactone (3OC12HSL) and butanoyl- homoserine lactone (C4HSL) ,respectively. LuxR, LasR and RhlR receptor have been synthesized and can bind to 3OC6HSL, 3OC12HSL and C4HSL, respectively.
In QS, not only activation promoters but also repression promoters have been used. The fact that LuxR and TraR promoter can function as both activation and repression has already been published in a paper*. We have characterized luxR promoter in order to confirm this feature of LuxR protein.
- Conversion of the Vibrio fischeri Transcriptional Activator, LuxR, to a Repressor
Genetic circuit
I, genetic circuit overview
We designed the following circuit. In Artificial Cooperation System, there are two types of E. coli, Cell A and Cell B. Cell A has resistance to kanamycin and Cell B has resistance to chloramphenicol originally.
Pcon: constitutive promoter.
Plux act: promoter activated by LuxR and 3OC6HSL. We call this promoter luxR activation promoter.
Plux rep: promoter repressed by LuxR and 3OC6HSL. We call this promoter luxR repression promoter.
Plas act: promoter activated by LasR and 3OC12HSL. We call this promoter lasR activation promoter.
Plas rep: promoter repressed by LasR and 3OC12HSL. We call this promoter lasR repression promoter.
In cell A, production of LasI is repressed by LuxR/3OC6HSL complex and Cm resistance gene is activated by LuxR/3OC6HSL complex. In cell B, production of LuxI is repressed by LasR/3OC12HSL complex and Kan resistance gene is activated by LasR/3OC12HSL complex. This means AHL of cell A and cell B repress each other indirectly. And AHL of cell A activates resistance gene of cell B, and AHL of cell B activates resistance gene of cell A. Apple gene is composed of crtEBIYZW and MpAAT1. This expresses only when the cell is helped.
- normal
In normal situation, Cell A and Cell B are competitors and recognize each other by using quorum sensing. First, LasI protein in Cell A produces 3OC12HSL. Second, these signal molecules diffuse through cell membranes and bind to LasR protein in Cell B. Third, LasR/3OC12HSL complex represses the production of LuxI protein. Similarly in cell B, LuxI protein produces 3OC6HSL. These signal molecules diffuse through cell membranes and bind to LuxR protein in Cell A. LuxR/OC6HSL complex represses the production of LasI protein. Although Cell A and Cell B have chloramphenicol and kanamycin resistance gene respectively, they don’t express in this situation. That’s because the concentration of 3OC12HSL and 3OC6HSL is too low to activate kanamycin resistance gene and chloramphenicol resistance gene, respectively.
- when Cell A is dying
As we mentioned, originally Cell A has resistance to kanamycin and doesn’t have resistance to chloramphenicol. On the other hand, Cell B has resistance to chloramphenicol and doesn’t have resistance to kanamycin. Therefore, number of only Cell A decreases after addition of chloramphenicol. This means 3OC12HSL decreases. And it also results in decreasing of 3OC12HSL and LasR complex in Cell B. By this process, Cell B notices that Cell A is dying and tries to rescue it.
- when Cell B tries to rescue Cell A
As we mentioned, the expression of luxI is repressed by LasR and 3OC12HSL complex. Therefore, the decrease of 3OC12HSL and LasR complex leads to overexpression of luxI and 3OC6HSL. It results in the activation of chloramphenicol resistance gene and this is followed by increase of the number of Cell A. Consequently, the mission of rescuing Cell A is completed!
II, importance of strength and threshold of promoters
To make our Artificial Cooperative System work, strength and threshold of promoters regulated by AHL are so important. For example, if the threshold of the resistance gene promoter is very low, resistance gene is activated by low AHL level. This means we can’t make a dangerous situation. And if the threshold of promoter of I gene is so high, the production level of I protein stays at highest level all the time. This means two types of cell help each other all the time. Even if the threshold of promoters is suitable, our system doesn’t work unless the strength of promoter is suitable. For example, when the strength of resistance gene promoter is low, cells can’t express adequate resistance gene and die. And if the strength of I protein promoter is low, cell can’t produce adequate amount of AHL to help the other cell.
Therefore, we have to design promoters whose threshold and strength are suitable for the Artificial Cooperative System.
III, tuning the threshold and strength of promoter
To initiate transcription from Plux, LuxR needs to bind the regulatory region upstream of -35, lux box. In the absence of AHL, LuxR can’t bind lux box and can’t initiate transcription from Plux. However in the presence of AHL, AHL binds LuxR and then, LuxR/AHL complex can bind lux box and initiate transcription from Plux.
Thus, how efficiently transcription initiate from Plux is determined by not only the concentration of LuxR/AHL, but the concentration of LuxR/AHL binding lux box. This concentration is determined by not only AHL, LuxR and LuxR/AHL concentration but also the binding affinity of LuxR/AHL complex and lux box. If the affinity is low, high concentration of LuxR/AHL complex is needed to initiate transcription efficiently. But if the affinity is high, high concentration of LuxR/AHL complex is not needed to initiate transcription efficiently. Therefore we can tune the AHL threshold of Plux by changing the sequence of lux box. These are represented by the following equations. And we can tune the strength of promoters by changing the sequence of -35 and -10 consensus sequence. Therefore we can obtain our ideal promoters by changing sequence.
In these equations,βrepresents Plux max activity, complex represents the concentration of LuxR/3OC6HSL complex and Kd represents the affinity of LuxR and lux box. S1 and S2 represents that Kd doesn’t determine the Plux max activity, but determines the complex concentration producing half level from this promoter. So, changing sequence of lux box doesn’t lead changing the Plux max activity. This leads changing threshold of Plux.
β represents Plux max activity, thus β represents the strength of -35 and -10 sequence. Therefore changing sequence of -35 and -10 leads changing Plux max activity.
Works
I, characterization of R0061 (promoter repressed by LuxR/3OC6HSL)
Introduction
We characterized luxR repression promoter. In the Artificial Cooperation System, we inserted chloramphenicol resistance coding sequence into this promoter. Thus, this promoter plays an important role in Artificial Cooperation System. We wanted to characterize the strength of this promoter which has never been done before in BioBrick in order to design new promoter based on this data. First, we confirmed R0061, which is a existing BioBrick promoter repressed by LuxR/3OC6HSL complex. To confirm this promoter, we constructed following two plasmids (fig〇〇and fig〇〇)
We introduced these two plasmid into DH5α.
Result
In the presence of 3OC6HSL(100nM), the fluorescence is lower than in the absence of 3OC6HSL. We used a fusion of placIQ (I14032) to gfp (K121013) as a positive control and used promoterless gfp (K121013) as a negative control. We measured fluorescence by flow cytometry 3 hour after addition of 100nM 3OC6HSL.
Conclution
This E. coli expresses LuxR constitutively and has GFP under Plux rep, thus it is supposed that GFP expression is repressed when AHL exists. Fig〇〇 shows that R0061 works as we expected.
II, designing the new promoters repressed by LuxR/3OC6HSL, K395008 and K395009.
Though R0061 is repressed by LuxR/3OC6HSL, the leaky expression is so high. That’s because -35 and -10 sequence of R0061 is the same as the -35 and -10 sequence of J23119 whose strength is the highest in BioBrick constitutive promoters.
Then we designed new BioBrick parts, K395008 and K395009, whose -35 and -10 sequence is different from R0061. The -35 and -10 sequence of K395008 is the same as that of J23108. The -35 and -10 sequence is the same as that of J23115. J23108 and J23115 are BioBrick constitutive promoters.
Why we chose J23108 and J23115 is that these expression levels are middle and low in BioBrick constitutive promoters. 2nd reason is that 3’ end nucleotide of -35 sequence of J23108 and J23115 is ‘A’ and that 5’ end nucleotide of -10 sequence 0f J23108 and J23115 is ‘T’. -35 and -10 overlap lux box.
III, characterization of K395008 (LuxR repression promoter)
Introduction
Even subtle changes in promoter may have distinct effects on the expression of gene. As we mentioned before, we designed a new promoter which is repressed by AHL and LuxR complex by changing one base of the existing BioBrick parts (BBa_R0061). We wanted to characterize this luxR repression promoter. Also, we wanted to confirm that this promoter is also repressed by AHL and LuxR but has different strength from the existing BioBrick part.
Result
After construction of K395195, we introduced K395195 and S03119 into DH5α. And we measured the fluorescence by flow cytometry. Fig 〇〇shows this result.
Addition of AHL caused the decrease in fluorescence intensity. The expression of GFP with AHL dropped to 1/3 comparing with the expression without AHL.
Conclusion
We confirmed that AHL repressed luxR repression promoter, K395008 as expected.
IV, characterization of R0062 (promoter activated by LuxR/3OC6HSL)
Introduction
We characterized luxR activation promoter. We inserted chloramphenicol resistance coding sequence into the downstream of this promoter. This promoter plays an important role in Artificial Cooperation System. We wanted to confirm strength of this promoter which has already been done before in BioBrick in order to design new promoter based on this data. First, we assayed R0062 which is an existing BioBrick promoter activated by LuxR/3OC6HSL complex. To confirm this promoter, we constructed following two plasmids (fig〇〇and fig〇〇)
We introduced two plasmid into DH5α. Next, we research the 3OC6HSL concentration dependence of Plux activity. We measured the fluorescence intensity under different concentration of AHL (0nM, 1nM, 3nM, 5nM, 10nM, 30nM, 50nM, 100nM. We measured the fluorescence by flow cytometry 3 hours after 3OC6HSL induction.
Result
In the absence of AHL, the fluorescence is low. In the contrast, the fluorescence is so high in the presence of 3OC6HSL(100nM), that’s 〇〇fold higher than in the absence of 3OC6HSL.
The previous experiment shows that Plux is worked. This means that Plux is activated by LuxR and 3OC6HSL.
Fig 〇〇is the result of measurement.
Conclusion
This E. coli expresses LuxR constitutively and has GFP under Plux act, thus it is supposed that GFP expression is activated when 3OC6HSL exists. We confirmed BioBricks, K395100 and S03119 (pSB3K3) worked correctly and the activity of R0062 is dependent on 3OC6HSL and the AHL threshold concentration is about 〇〇nM.