Team:LCG-UNAM-Mexico/Project
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<td class="bodyText"><p align="justify">The objective of this project is to modulate the extracellular nickel concentration through the regulation of its efflux pump. We plan to measure the change in the nickel concentration, and this can be achieved by measuring the change in the conductivity of the medium. These data will be interpreted and converted into a sound depending on the concentration read.<br> | <td class="bodyText"><p align="justify">The objective of this project is to modulate the extracellular nickel concentration through the regulation of its efflux pump. We plan to measure the change in the nickel concentration, and this can be achieved by measuring the change in the conductivity of the medium. These data will be interpreted and converted into a sound depending on the concentration read.<br> | ||
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- | <td class="bodyText"><p align="justify">The first of these is the one controlled by us through AHL. AHL enters the cell and forms a dimer with LuxR, which is under a constitutive promoter. This dimer serves as an activator of cI*, which represses RcnA. In this way we can express the concentration (and therefore the activity) of RcnA as a function of AHL. The second of these mechanisms is the natural regulation of the pump (RcnA) in response to the intracellular nickel concentration. When there is no nickel inside the cell, RcnR represses RcnA. However, when nickel enters the cell, it forms a dimer with RcnR and changes its conformation so it no longer represses RcnA. RcnA is then free to start pumping Ni out of the cell. We are keeping this because it is damaging to the bacteria to have the pump always on, and otherwise it would need a constant supply of AHL.</p> | + | <td class="bodyText"><p align="justify">Our system is conformed by two regulation mechanisms. The first of these is the one controlled by us through AHL. AHL enters the cell and forms a dimer with LuxR, which is under a constitutive promoter. This dimer serves as an activator of cI*, which represses RcnA. In this way we can express the concentration (and therefore the activity) of RcnA as a function of AHL. The second of these mechanisms is the natural regulation of the pump (RcnA) in response to the intracellular nickel concentration. When there is no nickel inside the cell, RcnR represses RcnA. However, when nickel enters the cell, it forms a dimer with RcnR and changes its conformation so it no longer represses RcnA. RcnA is then free to start pumping Ni out of the cell. We are keeping this because it is damaging to the bacteria to have the pump always on, and otherwise it would need a constant supply of AHL.</p> |
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<td class="bodyText"><p align="justify">The final result will be a biological system capable of modifying its surrounding medium. In addition, our measurements will allow us to model the dynamic behavior of the pump and the intra and extracellular nickel concentrations.<br></p> | <td class="bodyText"><p align="justify">The final result will be a biological system capable of modifying its surrounding medium. In addition, our measurements will allow us to model the dynamic behavior of the pump and the intra and extracellular nickel concentrations.<br></p> |
Revision as of 02:49, 31 July 2008
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