Team:LCG-UNAM-Mexico/Description
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==='''Main objective'''=== | ==='''Main objective'''=== | ||
- | We designed a kamikaze system that will prevent the spreading of phage infection. We fused T7’s promoter with the rRNAse domain of colicin E3 and GFP gene as a reporter. Colicin E3 is a toxin that cleaves 16s rRNAs in active ribosomes of E. Coli. Naive T7 will infect protected E. Coli which will start producing toxins that deactivate ribosomes. The result: No translation Machinery, no phages production and a heroic bacterium’s death. The main objective of The Defense System is to significantly reduce the burst size in order to allow bacteria to survive a phage infection process.<br><br> | + | We designed a kamikaze system that will prevent the spreading of phage infection. We fused T7’s promoter with the rRNAse domain of colicin E3, DNAse domain of colicin E9 and GFP gene as a reporter. Colicin E3 is a toxin that cleaves 16s rRNAs in active ribosomes of E. Coli. Naive T7/T3 will infect protected E. Coli which will start producing toxins that deactivate ribosomes. The result: No translation Machinery, no phages production and a heroic bacterium’s death. The main objective of The Defense System is to significantly reduce the burst size in order to allow bacteria to survive a phage infection process.<br><br> |
A virus infection is a process that takes place inside and individual but the real consequences of the infection become important at the population scale. In order to efficiently and accurately simulate the behaviour of The Defence System we need to implement two different kinds of approaches: an individual-based simulation and a population simulation, and then integrate them in a Multi-Scale Model.<br><br> | A virus infection is a process that takes place inside and individual but the real consequences of the infection become important at the population scale. In order to efficiently and accurately simulate the behaviour of The Defence System we need to implement two different kinds of approaches: an individual-based simulation and a population simulation, and then integrate them in a Multi-Scale Model.<br><br> | ||
- | Our construction for the Defence System also integrates LuxI in order to create an Alarm Response. Once a bacterium gets infected T7 promoter will activate the transcription of E3, GFP and LuxI so AHL will be produced and diffused to the extracellular environment.<br><br> | + | Our construction for the Defence System also integrates LuxI in order to create an Alarm Response. Once a bacterium gets infected by T7/T3 promoter will activate the transcription of E3,E9, GFP and LuxI so AHL will be produced and diffused to the extracellular environment.<br><br> |
In order to simulate the spatial dynamics of the Defence System we designed and implemented a Cellular Automata (CA). Using the CA we can approach several problems at the same time: E. Coli movement and duplication, AHL and phage diffusion and the infection process. Parameters for the bacteria in the CA are random variables so we sample the distributions created by the Stochastic Kinetic Simulations:<br><br> | In order to simulate the spatial dynamics of the Defence System we designed and implemented a Cellular Automata (CA). Using the CA we can approach several problems at the same time: E. Coli movement and duplication, AHL and phage diffusion and the infection process. Parameters for the bacteria in the CA are random variables so we sample the distributions created by the Stochastic Kinetic Simulations:<br><br> | ||
Finally we create the multi-scale model sampling the distributions created by the Stochastic Kinetic Simulations and use those values as parameters for the cells in the CA. | Finally we create the multi-scale model sampling the distributions created by the Stochastic Kinetic Simulations and use those values as parameters for the cells in the CA. |
Revision as of 23:30, 21 October 2009