Team:LCG-UNAM-Mexico/Experiments/Design

From 2008.igem.org

(Difference between revisions)
Line 117: Line 117:
         <div align="center">
         <div align="center">
           <p><span class="calHeader"><a name="Devices"></a>System</span></p>
           <p><span class="calHeader"><a name="Devices"></a>System</span></p>
-
           <p align="justify"> &nbsp; First of all, we needed a system that could <span dir="ltr" id=":1s">cause a change in its medium conductivity</span>. An extrusion pump seemed to be the best way to achieve this. Once this was devised, we needed a way to regulate the system. <span dir="ltr" id=":1s">We  decided to use a negative regulator because it's the only way to  transcriptionally regulate the expression of a gene in a definitive way.</span></p>
+
           <p align="justify"> &nbsp; First of all, we needed a system that could <span dir="ltr" id=":1s">cause a change in its medium resistivity</span>. An extrusion pump seemed to be the best way to achieve this. Once this was devised, we needed a way to regulate the system. <span dir="ltr" id=":1s">We  decided to use a negative regulator because it's the only way to  transcriptionally regulate the expression of a gene in a definitive way.</span></p>
           <p align="justify"><br>
           <p align="justify"><br>
   &nbsp; We had to be able to restart our system, so we could add a signal at  anytime. This could be accomplished with an induction signal that  disappeared rapidly after its involvement. The need of a link between  the inductor signal and the repressor, lead  us to include a little regulation cascade. This cascade allows us to  add new steps which might increase our system’s complexity.<br>
   &nbsp; We had to be able to restart our system, so we could add a signal at  anytime. This could be accomplished with an induction signal that  disappeared rapidly after its involvement. The need of a link between  the inductor signal and the repressor, lead  us to include a little regulation cascade. This cascade allows us to  add new steps which might increase our system’s complexity.<br>

Revision as of 14:29, 29 October 2008

LCG-UNAM-Mexico:Experiments

Header image
iGEM 2008 TEAM
line decor
  
line decor

 
 
 
 




Design

System

Sensing dispositive

System

  First of all, we needed a system that could cause a change in its medium resistivity. An extrusion pump seemed to be the best way to achieve this. Once this was devised, we needed a way to regulate the system. We decided to use a negative regulator because it's the only way to transcriptionally regulate the expression of a gene in a definitive way.


  We had to be able to restart our system, so we could add a signal at anytime. This could be accomplished with an induction signal that disappeared rapidly after its involvement. The need of a link between the inductor signal and the repressor, lead us to include a little regulation cascade. This cascade allows us to add new steps which might increase our system’s complexity.

The components selected to fulfill the system requirements are enlisted in the next table:

 

Devices

 

Device BBa_K119009: The extrusion pump.


Our aim is to manipulate the transcription of rcnA by an inhibitory signal while maintaining the natural regulation of rcnA through RcnR. To achieve this the device contains a CI dependent promoter, RcnR binding site and the RcnA extrusion pump inserted in the vector pBBR1MCS-5.

 

Devices BBa_K119010/BBa_K119011: The regulatory device

In order to control the RcnA activity this device includes the gene encoding LuxR under the regulation TetR constitutive promoter followed by cI, which will repress RcnA in the prescence of AHL:LuxR. The last component of the device is the gene encoding AiiA. In BBa_K119010 lacZ promoter is upstream of AiiA, while BBa_K119011 carries a mutated version of it. The plasmid carrying this device will be PRK415.

 

 

 

 

 

Sensing dispositive

 

References


1.-Koch, D., Nies, D.H., Grass G..”The RcnRA (YohLM) system of Escherichia coli: A connection between nickel cobalt and iron homeostasis”.2006.

2.-Rodrigue A. Et al.”Identification of rcnA (yohM), a Nickel and Cobalt Resistance Gene in Esherichia coli” 2005.

3.-Kovach et al.,”pBBR1MCS: a broad-host-range cloning vector”.1994

4.-

5.-link a chiba, ahorita lo pongo

6.-Whiteheada N.A., Barnada A.M.L., Slaterra H..”Quorum-sensing in Gram-negative bacteria”2001.

7.-Fuqua, W.C., Winans, S.C., Greenber, E.P..”Quorum sensing in bacteria: The LuxR-LuxI family of cell densisty-responsive transcriptional regulators”.2001.

8.-Salmond, G.P.C., Bycroft, B.W., Stewart, G.S.A.B., Williams, P..”The bacterial 'enigma': Crackin the code of cell-cell communication”.1995.

9.-Y. Dong and L. Zhang, “Quorum sensing and quorum-quenching enzymes”.2005.

10.-Atsumi, S., Little, J.W.. “A synthetic phage λ regulatory circuit”. 2006.

11.- Karzai, A.W.."the Ssra-SmpB system for protein tagging, directed degradation and ribosome rescue".2000.

12.-Keiler, K.C.et al. "Role of a peptide-tagging system in degradation of proteins synthesized from damaged messenger RNA".1996.


13.- articulo de lacz de cursos q no encontre =S.

14.-J. Togashi, K. Ueda and T. Namai, “Overwintering of Erwinia carotovora subsp. carotovora in diseased tissues in soil and its role as inoculum for soft rot of Chinese cabbage”.2001.

15.-Y. Dong and L. Zhang, “Quorum sensing and quorum-quenching enzymes”.2005.

16.-N.T. Keen, S. Tamaki, D. Kobayashi, and D. Trollinger. 1998.

 




ribbon