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<p><justify>Mathematical modeling acts as engineering part in Synthetic Biology to link theoretical reaction mechanisms and lab work result. Our goal in modeling is to predict system behavior and give insight to the wet lab team. | <p><justify>Mathematical modeling acts as engineering part in Synthetic Biology to link theoretical reaction mechanisms and lab work result. Our goal in modeling is to predict system behavior and give insight to the wet lab team. | ||
− | There are three main aspects of our modeling: <p><b>1) quorum sensing time to predict when biofilm formed</b></p> | + | There are three main aspects of our modeling: |
+ | <p><b>1) quorum sensing time to predict when biofilm formed</b></p> | ||
+ | <p><b>2) the rate of PETase production</b></p> | ||
+ | <p><b>3) PET hydrolysis by PETase with and without biofilm</b></p>. These aspects modeled, compared and fitted by the experimental data, thus giving numerical trends from the aspects before wet lab team does labwork in the lab. | ||
<p>All four models have data that needed each other. The rate of bacteria growth affects the amount of biofilm produced. According to our models, the rate of biofilm growth heavily depends on μ (specific growth rate) and the initial amount of inoculated bacteria. Bacteria produce mRNA, which influences PETase production until it reaches steady state. This steady state value of PETase production will be set as the initial amount of PETase in calculating the rate of PET degradation.</justify></p></p> | <p>All four models have data that needed each other. The rate of bacteria growth affects the amount of biofilm produced. According to our models, the rate of biofilm growth heavily depends on μ (specific growth rate) and the initial amount of inoculated bacteria. Bacteria produce mRNA, which influences PETase production until it reaches steady state. This steady state value of PETase production will be set as the initial amount of PETase in calculating the rate of PET degradation.</justify></p></p> | ||
Revision as of 18:50, 30 October 2017
Modelling
Modelling Towards Precise Prediction
1) quorum sensing time to predict when biofilm formed 2) the rate of PETase production 3) PET hydrolysis by PETase with and without biofilm All four models have data that needed each other. The rate of bacteria growth affects the amount of biofilm produced. According to our models, the rate of biofilm growth heavily depends on μ (specific growth rate) and the initial amount of inoculated bacteria. Bacteria produce mRNA, which influences PETase production until it reaches steady state. This steady state value of PETase production will be set as the initial amount of PETase in calculating the rate of PET degradation.
Quorum Sensing
Here ODEs that we used :
Growth curve
AI-2 Production
Biofilm Formation
PETase Transcription
1. No inclusion body is produced during the transcription. Consecutively, there’s also no TetR produced during the transcription.
2. Initally, there are 0.05 μM of mRNA and zero amount of PETase.
There, the differential equations of each parameter obtained through the analysis of mass balance are :Rate of PET Degradation with Biofilm
Based on illustration above, assumptions that we used are : 1. Biofilm covered E. coli from the effect of nutrient solution, however, the bottom section of E. coli is contacted with PET. 2. Corellation of q and qm, So equation 1 can be rewritten as : Based on assumptions that used in [], we get : Reaction mechanisms of PET degradation are stated below. We can derive differential equations that we need from reaction mechanisms. Here is coupled ODEs that we used to determine rate of PETase formation and degradation of PET with biofilm forming based on assumptions that stated above. Whereas PET defined as PET, E as PETase, and P is ethylene terephtalate, the product from PET degradation by PETase.
Rate of PET Degradation without Biofilm
Paragraph apapun