Team:PKU Beijing/Project/AND Gate 1/Inducible System Result

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==='''Construction result'''===
Input promoters construction:   
Input promoters construction:   
In the AND gate, we used five different inducible promoters as inputs: pBad (respond to L-arabinose), pSal (respond to salicylate), pLac (respond to IPTG), pTet (respond to tetracycline), luxP (respond to homoserine lactone). When the inducing small molecule in presence, the promoter is activate, for example, IPTG can activate pLac.  
In the AND gate, we used five different inducible promoters as inputs: pBad (respond to L-arabinose), pSal (respond to salicylate), pLac (respond to IPTG), pTet (respond to tetracycline), luxP (respond to homoserine lactone). When the inducing small molecule in presence, the promoter is activate, for example, IPTG can activate pLac.  

Revision as of 14:26, 16 October 2009

 

Contents

Construction result

Input promoters construction: In the AND gate, we used five different inducible promoters as inputs: pBad (respond to L-arabinose), pSal (respond to salicylate), pLac (respond to IPTG), pTet (respond to tetracycline), luxP (respond to homoserine lactone). When the inducing small molecule in presence, the promoter is activate, for example, IPTG can activate pLac. We have constructed four of these inducible systems (including the activator or repressor protein and promoter) and used one directly from other parts. The general pattern is like this:

PKU Generater Promoter Forward.png

They are: BBa_K228004: NahR-pSal system; BBa_K228009: AraC-pBad system; BBa_K228817: lacI-pLac system; BBa_K228818: tetR-pTet system. They are not only composite parts which can be used in our project, but also valuable devices employed in other designs or circuits. For the luxR-luxP system, we simply utilized the parts: BBa_J09855, which is designed and constructed by iGEM2006_Pennstate.

Input promoters test: In order to characterize the AND gate (e.g. the transfer function), the activities of these promoters should be measured independently by constructing GFP (with strong RBS B0034) downstream the promoters and testing the output in response to the small-molecular inducers.

PKU Promoter GFP.png

Therefore we successfully fused these promoters to GFP and test results are following:

aTc Sensor

The tetR-pTet system (parts: K228820, mainly by Shuke Wu) The colonies which contain the plasmid become very green 'without' inducing and are not greener after inducing. The evidence without inducing is on Fig1a, and the data after inducing are not showed here.

Discussion: the leakage is obvious and the reasons may lie in the constitutive promoter we used to drive the expression of tetR and the LVA tag of tetR coding sequence. The constitutive promoter we used is pCat which is a medium promoter (refer to parts BBa_I14033: http://partsregistry.org/wiki/index.php?title=Part:BBa_I14033), while the natural promoter of tetR is pTet itself (http://en.wikipedia.org/wiki/Tetracycline_controlled_transcriptional_activation). It is likely that the expression of tetR is insufficient to repress pTet. Another possible reason is the LVA tail of the tetR (refer to BBa_C0040 http://partsregistry.org/Part:BBa_C0040), and its function is for rapid degradation the protein. As a natural result, the amount of tetR may not enough to repress the pTet.

Fig1. the result of tet & lac promoter systems. Fig 1a is tet system, the colonies are very green under blue light, without inducing, and the upper plate is for comparison. Fig 1b is lac system, the colonies are very green under blue light, without inducing, and the upper plate is for comparison.

IPTG Sensor

The lacI-pLac system (Parts: K228819, mainly by Shuke Wu) The result is similar to the tetR system. The colonies which contain the plasmid become very green without inducing and are not greener after inducing. The evidence without inducing is on Fig1b, and the data after inducing are not showed here.

Nevertheless, we found another way to bypass the problem. That is making use of the lacI on the F plasmid of E. coli strain JM109 (refer to http://ecoliwiki.net/colipedia/index.php/JM109). Because the F plasmid is one copy per cell, if we can directly use the promoter pLac (BBa_R0010) on the low copy plasmid such as pSB4K5, the endogenous lacI can repress the pLac. Thus we constructed the simplified system (Parts: K228821) and tested it by different concentration of IPTG (for more detail refer to: https://2009.igem.org/Team:PKU_Beijing/Notebook/Protocol/Chemical_Inducible_GFP). The result is promising (Fig 2).

Fig2. GFP expression of lac system. The points are original data, and the red and blue means different groups.

However, there is still a problem in this simplified system: the loss of F plasmid of JM109 may lead to activation of promoter pLac without inducing. From the plate (without inducing), we found that some parts of some colonies become very green, while else parts are still in normal color (Fig 3). Furthermore, the stronger evidence is from flow cytometry: there is obvious two different peaks. All these suggest that one group of cell contain F plasmid while the F plasmids of another group are lost (Fig 4a, b & c).

Fig3. the JM109 colonies contained low copy pLac. Some small parts of the colonies become very green, while others are still not green. It suggest that some E.coli lost their F plasmids

HSL Sensor



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