Hakimbazol (Talk | contribs) |
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<h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 60px; text-align: center; color: #1c2922">Modelling Towards Precise Prediction</h1> | <h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 60px; text-align: center; color: #1c2922">Modelling Towards Precise Prediction</h1> | ||
− | <p>Mathematical modelling acts as engineering part in Synthetic Biology to be link between theoritical in reaction mechanisms and realisation in labwork. Our goal in modelling is to predict system behavior and give insight from our prediction how the system can (or must) be improved to wetlab team.</p> | + | <p><justify>Mathematical modelling acts as engineering part in Synthetic Biology to be link between theoritical in reaction mechanisms and realisation in labwork. Our goal in modelling is to predict system behavior and give insight from our prediction how the system can (or must) be improved to wetlab team.</justify></p> |
− | <p>There are four aspects that focused in our modelling, whiches are quorum sensing time, rate of PETase production and rate of PET hydrolysis by PETase with and without biofilm. These aspects modelled and then compared and fitted by the experiment data to ensure model can be used to predict and also to give numerical trends from the aspects that we stated above, before wetlab team do labwork in the lab.</p> | + | <p><justify>There are four aspects that focused in our modelling, whiches are quorum sensing time, rate of PETase production and rate of PET hydrolysis by PETase with and without biofilm. These aspects modelled and then compared and fitted by the experiment data to ensure model can be used to predict and also to give numerical trends from the aspects that we stated above, before wetlab team do labwork in the lab.</justify></p> |
− | <p>All four models have data that <b>needed each other</b>. 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 bacterias. Bacterias produce mRNA, which influences the 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.</p> | + | <p><justify>All four models have data that <b>needed each other</b>. 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 bacterias. Bacterias produce mRNA, which influences the 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> |
<h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">Quorum Sensing</h1> | <h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">Quorum Sensing</h1> | ||
<p></p> | <p></p> | ||
− | <p>Quorum sensing mechanism was used to form biofilm of <i>E.coli</i> strain Top10, BL21 and DH5α that used in labwork. We have modeled growth curve of <i>E.coli</i> to determine when we must move <i>E.coli</i> colony from inoculum flask to reaction flask that contains PET. Besides growth curve, we have modeled some coupled ODEs to model growth curve, AI-2 production that affects signaling, and biofilm formation. AI-2 production in <i>E.coli</i> was used as colony signal of quorum sensing until it reaches specific points and finally form biofilm that affected by its quorum sensing by AI-2 signaling. We use Hill kinetics function as our approach to model AI-2 production and biofilm formation. Based on model that we built and confirmation from wetlab team, we found inoculation time until <i>E.coli</i> reaches quorum sensing condition is <b>10 hours</b>. Not only time that necessary for quorum sensing condition, we found from <b>model</b>, parameter that <b>affect significantly</b> to <b>biofilm formation</b> was <b>specific growth rate (μ) and initial amount of bacteria that will be inoculated</b> that <b>insightful to wetlab team</b> when construct their parts.</p> | + | <p><justify>Quorum sensing mechanism was used to form biofilm of <i>E.coli</i> strain Top10, BL21 and DH5α that used in labwork. We have modeled growth curve of <i>E.coli</i> to determine when we must move <i>E.coli</i> colony from inoculum flask to reaction flask that contains PET. Besides growth curve, we have modeled some coupled ODEs to model growth curve, AI-2 production that affects signaling, and biofilm formation. AI-2 production in <i>E.coli</i> was used as colony signal of quorum sensing until it reaches specific points and finally form biofilm that affected by its quorum sensing by AI-2 signaling. We use Hill kinetics function as our approach to model AI-2 production and biofilm formation. Based on model that we built and confirmation from wetlab team, we found inoculation time until <i>E.coli</i> reaches quorum sensing condition is <b>10 hours</b>. Not only time that necessary for quorum sensing condition, we found from <b>model</b>, parameter that <b>affect significantly</b> to <b>biofilm formation</b> was <b>specific growth rate (μ) and initial amount of bacteria that will be inoculated</b> that <b>insightful to wetlab team</b> when construct their parts.</justify></p> |
<p>Here ODEs that we used :</p> | <p>Here ODEs that we used :</p> | ||
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<h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">PETase Transcription</h1> | <h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">PETase Transcription</h1> | ||
− | <p>After we have inoculated bacteria until biofilm was formed, process that we focused is PETase production in bacterium body, or usually called transcription. | + | <p><justify>After we have inoculated bacteria until biofilm was formed, process that we focused is PETase production in bacterium body, or usually called transcription.</justify> |
The illustration of transcription of PETase is given below. | The illustration of transcription of PETase is given below. | ||
<p><center><img src="https://static.igem.org/mediawiki/2017/5/5d/Transkripsi.gif" style="width: auto; height: auto;" align="middle"/></center></p> | <p><center><img src="https://static.igem.org/mediawiki/2017/5/5d/Transkripsi.gif" style="width: auto; height: auto;" align="middle"/></center></p> | ||
− | We define M(t) and C(t) as functions versus time (in further discussions will be just written as M and C). Before going to differential equations that illustrate rate of mRNA (symbolized as M) and PETase production (symbolized by C), we made several assumptions for the model: | + | <justify>We define M(t) and C(t) as functions versus time (in further discussions will be just written as M and C). Before going to differential equations that illustrate rate of mRNA (symbolized as M) and PETase production (symbolized by C), we made several assumptions for the model:</justify> |
<p>1. No inclusion body is produced during the transcription. Consecutively, there’s also no TetR produced during the transcription.</p> | <p>1. No inclusion body is produced during the transcription. Consecutively, there’s also no TetR produced during the transcription.</p> | ||
<p>2. Initally, there are 0.05 μM of mRNA and zero amount of PETase.</p> | <p>2. Initally, there are 0.05 μM of mRNA and zero amount of PETase.</p> | ||
− | There, the differential equations of each parameter obtained through the analysis of mass balance are | + | There, the differential equations of each parameter obtained through the analysis of mass balance are : |
<p><center><img src="https://static.igem.org/mediawiki/2017/3/34/CodeCogsEqn_%283%29.gif" style="width: auto; height: auto;" align="middle"/></center></p> | <p><center><img src="https://static.igem.org/mediawiki/2017/3/34/CodeCogsEqn_%283%29.gif" style="width: auto; height: auto;" align="middle"/></center></p> | ||
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We choose α<sub>m</sub> = 0.011 μmin<sup>-1</sup>, γ<sub>m</sub>= 0.009 μ<sup>-1</sup>, γ<sub>C</sub>= 0.04 μmin<sup>-1</sup>. | We choose α<sub>m</sub> = 0.011 μmin<sup>-1</sup>, γ<sub>m</sub>= 0.009 μ<sup>-1</sup>, γ<sub>C</sub>= 0.04 μmin<sup>-1</sup>. | ||
− | Each of the differential equation is solved analytically using the MATLAB. Through the graph, we can see that at the steady state, the rate of production of PETase is 1,220 mg/(liter∙h) which attained at 600/60 = 10 h. Datum of PETase production will be used as the initial value in PET degradation. | + | <justify>Each of the differential equation is solved analytically using the MATLAB. Through the graph, we can see that at the steady state, the rate of production of PETase is 1,220 mg/(liter∙h) which attained at 600/60 = 10 h. Datum of PETase production will be used as the initial value in PET degradation.</justify> |
</p> | </p> | ||
<h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">Rate of PET Degradation with Biofilm</h1> | <h1 class="ITB_h1" style="padding-bottom: 30px; margin-bottom: 30px; border-bottom: 2px solid #1c2922 !important; padding-left: 30px; font-size: 30px; text-align: justify; color: #1c2922">Rate of PET Degradation with Biofilm</h1> | ||
− | <p>Based on PETase production model, we use value of PETase production to be an initial value to degrade PET. The system that we designed illustrated as below. | + | <p><justify>Based on PETase production model, we use value of PETase production to be an initial value to degrade PET. The system that we designed illustrated as below. |
<p>Based on illustration above, assumptions that we used are :</p> | <p>Based on illustration above, assumptions that we used are :</p> | ||
<p>1. Biofilm is covered <i>E. coli</i> from effect of nutrient solution, but bottom section of <i>E. coli</i> is contacted with PET.</p> | <p>1. Biofilm is covered <i>E. coli</i> from effect of nutrient solution, but bottom section of <i>E. coli</i> is contacted with PET.</p> | ||
<p>2. </p> | <p>2. </p> | ||
− | <p>Enzymatic reaction of PETase is assumed to obey two mechanisms reaction, i.e. Langmuir adsorption isotherm that applied in hydrolysis reaction that using Michaelis-Menten kinetics. One of main reason Michaelis Menten kinetics not to be applied in PET degradation mechanism by PETase is PETase hydrolysis involves heterogeneous reaction []. Based on Langmuir adsorption isotherm, we can derive mathematical expression that implemented to Michaelis Menten kinetics. | + | <p><justify>Enzymatic reaction of PETase is assumed to obey two mechanisms reaction, i.e. Langmuir adsorption isotherm that applied in hydrolysis reaction that using Michaelis-Menten kinetics. One of main reason Michaelis Menten kinetics not to be applied in PET degradation mechanism by PETase is PETase hydrolysis involves heterogeneous reaction []. Based on Langmuir adsorption isotherm, we can derive mathematical expression that implemented to Michaelis Menten kinetics. </justify> |
Langmuir adsorption isotherm equation is :</p> | Langmuir adsorption isotherm equation is :</p> | ||
− | <p>Whereas q is quality of PET enzyme adsorption by unit quality PET, g; qm is the maximum adsorption of PET enzyme by unit quality PET, g; Ka is the adsorption dissociation constant, mL/g; Ef is the concentration of free PET enzyme in the solution, g/mL.</p> | + | <p><justify>Whereas q is quality of PET enzyme adsorption by unit quality PET, g; qm is the maximum adsorption of PET enzyme by unit quality PET, g; Ka is the adsorption dissociation constant, mL/g; Ef is the concentration of free PET enzyme in the solution, g/mL.</justify></p> |
<p>Corellation of q and qm,</p> | <p>Corellation of q and qm,</p> | ||
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<p>Based on assumptions that used in [], we get :</p> | <p>Based on assumptions that used in [], we get :</p> | ||
− | <p>K is a constant connecting the three characters and A represents the area of the PET film. Langmuir adsorption equation linked with the second step of hydrolysis reaction process, here, the equation above is the key to connect the two step, and the value of the PET•S will be used in the hydrolysis reaction.</p> | + | <p><justify>K is a constant connecting the three characters and A represents the area of the PET film. Langmuir adsorption equation linked with the second step of hydrolysis reaction process, here, the equation above is the key to connect the two step, and the value of the PET•S will be used in the hydrolysis reaction.</justify></p> |
<p>Reaction mechanisms of PET degradation are stated below.</p> | <p>Reaction mechanisms of PET degradation are stated below.</p> |
Revision as of 17:09, 30 October 2017
Modelling
Modelling Towards Precise Prediction
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 is covered E. coli from effect of nutrient solution, but 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
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