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Team:Bologna/Modeling
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All the biochemical reactions occurring in the testing circuit are listed in Fig. 1, Fig. 2 and Fig. 2 | All the biochemical reactions occurring in the testing circuit are listed in Fig. 1, Fig. 2 and Fig. 2 | ||
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| - | [[Image: | + | [[Image:Reazioniagg.jpg|center|940px|thumb|Figure 1: GFP transcription and GFP translation (left); LacI transcription, LacI translation and LacI dimerization (right) ]]<br> |
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|[[Image:Pag3.jpg|450px|thumb|Figure 2: Other Chemical Reactions]] | |[[Image:Pag3.jpg|450px|thumb|Figure 2: Other Chemical Reactions]] | ||
Revision as of 02:17, 22 October 2009
| HOME | TEAM | PROJECT | SOFTWARE | MODELING | WET LAB | PARTS | HUMAN PRACTICE | JUDGING CRITERIA |
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A. Einstein
Contents |
Introduction
We developed a mathematical model to simulate the response of the testing circuit (Fig. 1).
Mathematical Model
Transcription and translation processes are considered similar to a second oder kinetics like an enzymatic reaction: RNA polymerase and ribosome perform enzymes' role, while gene promoter and RBS sequence act as substrates. The binding between enzyme and substrate leads to the formation of a complex, yielding to the final product: mRNA for the polymerase-promoter complex and protein for the ribosome-RBS complex.
Reactions
All the biochemical reactions occurring in the testing circuit are listed in Fig. 1, Fig. 2 and Fig. 2
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Symbol definitions are listed in Table 1
Differential Equations
The differential equations describing the above biochemical reaction are obtained appling the law of mass action.
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Simulations
To simulate the model we implemented the equation in Simulink (Figure 3 and Figure 4).
Results of model simulation are shown in the wet lab parts characterization.
