Team:Newcastle/Modelling

From 2009.igem.org

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=Computational Modelling=
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= Computational Modelling =
[[Image:Team Newcastle iGem 2009 08-07-09 no 7.JPG|300px|center]]
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==[https://2009.igem.org/Team:Newcastle/Modeling/Overview Overview of Our System]==
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The modelling in our 2009 iGEM project, BacMan, can be split into a number of sections - the [[Team:Newcastle/Modelling/Stochastic|Stochastic Switch]], [[Team:Newcastle/Modelling/Degradation|Degradation system]], [[Team:Newcastle/Modelling/MetalIntake|Metal Intake]], [[Team:Newcastle/SporulationTuning#Modelling|Sporulation Tuning]] and [[Team:Newcastle/Modelling/Population|Population Simulation]]. We are particularly proud of our Population Simulation Model as it combines distributed computing, agent based and cellular models.
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For computational modelling, we are using a number of technologies, including [[Team:Newcastle/Java|Java]], [[Team:Newcastle/Matlab|Matlab]], [[Team:Newcastle/Amazon EC2|Amazon EC2]], [[Team:Newcastle/Microbase|Microbase]], [[Team:Newcastle/SBML|SBML]] and [[Team:Newcastle/CellML|CellML]].
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== Sub-projects ==
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=== Stochastic Switch ===
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: '' See [[Team:Newcastle/Modelling/Stochastic|Stochastic Switch Model]]''
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We have modelled our stochastic switch.
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We also designed an inducible protein degradation system for our switch.
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: '' See [[Team:Newcastle/Modelling/Degradation|Degradation Model]]''
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=== Population Modelling ===
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: '' See [[Team:Newcastle/Modelling/Population|Population Simulation]]''
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One of the models which we are producing is one concerning the population numbers of our bacteria. It looks at how our additions to the DNA may affect the growth of the bacterial population.
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=== Sporulation Tuning ===
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: '' See [[Team:Newcastle/Modelling/KinAExpression|KinA Expression Model]]''
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The KinA Expression model describes how KinA is expressed.
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<br>
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: '' See [[Team:Newcastle/Modelling/SporulationTuning|Sporulation Tuning Model]]''
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Building on the KinA Expression model, the phosphorelay is implented into our model, using the expression of KinA to induce sporulation.
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<br>
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: '' See [[Team:Newcastle/Modelling/SinOperon|Sin Operon Model]]''
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The Sin Operon model is used to repress sporulation, in view of making our model more realistic.
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<br>
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=== Metal Intake ===
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: '' See [[Team:Newcastle/Modelling/MetalIntake|Metal Intake Model]]''
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Another of our models looks at metal intake. Specifically this looks at Cadmium transport throughout our bacteria.
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Latest revision as of 20:58, 21 October 2009


Computational Modelling

Team Newcastle iGem 2009 08-07-09 no 7.JPG


The modelling in our 2009 iGEM project, BacMan, can be split into a number of sections - the Stochastic Switch, Degradation system, Metal Intake, Sporulation Tuning and Population Simulation. We are particularly proud of our Population Simulation Model as it combines distributed computing, agent based and cellular models.

For computational modelling, we are using a number of technologies, including Java, Matlab, Amazon EC2, Microbase, SBML and CellML.

Sub-projects

Stochastic Switch

See Stochastic Switch Model

We have modelled our stochastic switch.

We also designed an inducible protein degradation system for our switch.

See Degradation Model

Population Modelling

See Population Simulation

One of the models which we are producing is one concerning the population numbers of our bacteria. It looks at how our additions to the DNA may affect the growth of the bacterial population.

Sporulation Tuning

See KinA Expression Model

The KinA Expression model describes how KinA is expressed.

See Sporulation Tuning Model

Building on the KinA Expression model, the phosphorelay is implented into our model, using the expression of KinA to induce sporulation.

See Sin Operon Model

The Sin Operon model is used to repress sporulation, in view of making our model more realistic.

Metal Intake

See Metal Intake Model

Another of our models looks at metal intake. Specifically this looks at Cadmium transport throughout our bacteria.




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