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<div id="main_contents"> | <div id="main_contents"> | ||
<div id="page_header" class="container container_top"> | <div id="page_header" class="container container_top"> | ||
− | <h1 align="center"> | + | <h1 align="center">Detailed description</h1> |
</div><!-- page_header --> | </div><!-- page_header --> | ||
<div id="modeling_development" class="container"> | <div id="modeling_development" class="container"> | ||
<div id="modeling_development_header" class="container_header"> | <div id="modeling_development_header" class="container_header"> | ||
− | <h2><span> | + | <h2><span>Model development</span></h2> |
</div><!-- /modeling_development_header --> | </div><!-- /modeling_development_header --> | ||
<div id="modeling_development_contents" class="container_contents"> | <div id="modeling_development_contents" class="container_contents"> | ||
<p class="normal_text">To simulate the cell-cell communication system, we developed an ordinary differential equation model. | <p class="normal_text">To simulate the cell-cell communication system, we developed an ordinary differential equation model. | ||
− | The following | + | The following segments describe in detail how the equations were developed with the <span style ="font-style : italic">mazEF</span> system. |
− | + | </p> | |
</div><!-- modeling_development_contents --> | </div><!-- modeling_development_contents --> | ||
<div id="modeling_maz_contents" class="container_contents"> | <div id="modeling_maz_contents" class="container_contents"> | ||
+ | <div style="text-align: center;"> | ||
<a href="https://static.igem.org/mediawiki/2016/5/52/T--Tokyo_Tech--Model_Details_1.png"><img src="https://static.igem.org/mediawiki/2016/5/52/T--Tokyo_Tech--Model_Details_1.png" /></a> | <a href="https://static.igem.org/mediawiki/2016/5/52/T--Tokyo_Tech--Model_Details_1.png"><img src="https://static.igem.org/mediawiki/2016/5/52/T--Tokyo_Tech--Model_Details_1.png" /></a> | ||
− | <p class="caption"><span style="font-weight: bold;">Fig. | + | <p class="caption"><span style="font-weight: bold;">Fig.5-5-1. The <span style ="font-style : italic">mazEF</span> system gene circuit</span></p></div> |
<div id="modeling_detail" class="off"> | <div id="modeling_detail" class="off"> | ||
<div id="modeling_detail_wrapper"> | <div id="modeling_detail_wrapper"> | ||
<div id="modeling_detail_expressions"> | <div id="modeling_detail_expressions"> | ||
− | <h2>Differencial | + | <h2>Differencial equations</h2> |
<h3>Snow White</h3> | <h3>Snow White</h3> | ||
\begin{equation} | \begin{equation} | ||
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\end{equation} | \end{equation} | ||
\begin{equation} | \begin{equation} | ||
− | \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} | + | \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} |
\end{equation} | \end{equation} | ||
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<h3>Prince</h3> | <h3>Prince</h3> | ||
\begin{equation} | \begin{equation} | ||
− | \frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^ | + | \frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{AmiE}] |
\end{equation} | \end{equation} | ||
\begin{equation} | \begin{equation} | ||
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</div><!-- /modeling_detail_expressions --> | </div><!-- /modeling_detail_expressions --> | ||
<div id="modeling_detail_parameter"> | <div id="modeling_detail_parameter"> | ||
− | <h2>Explanation about | + | <h2>Explanation about parameters</h2> |
<table border="1" style="margin: auto;"> | <table border="1" style="margin: auto;"> | ||
<tbody> | <tbody> | ||
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<p class="normal_text" style="text-align:center;"><a href="javascript:void(0);" onClick="show('modeling_detail');" class="showHidden">Expressions</a></p> | <p class="normal_text" style="text-align:center;"><a href="javascript:void(0);" onClick="show('modeling_detail');" class="showHidden">Expressions</a></p> | ||
<ul id="modeling_maz_list" class="non_dotted_list"> | <ul id="modeling_maz_list" class="non_dotted_list"> | ||
− | <li><h2>1. Cell | + | <li><h2>1. Cell population</h2> |
<p>$$ \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} $$ <br /> $$ \tag{1-1} $$</p> | <p>$$ \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} $$ <br /> $$ \tag{1-1} $$</p> | ||
− | <p>$$ | + | <p>$$ |
\frac{dP_{Queen}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Queen}$$ <br /> $$ \tag{1-2} $$</p> | \frac{dP_{Queen}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Queen}$$ <br /> $$ \tag{1-2} $$</p> | ||
− | <p>$$ | + | <p>$$ |
\frac{dP_{Prince}}{dt} = g\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Prince} \tag{1-3} $$ </p> | \frac{dP_{Prince}}{dt} = g\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Prince} \tag{1-3} $$ </p> | ||
− | <p class="caption"><span style="font-weight: bold;">Eq.1. </span> Differential | + | <p class="caption"><span style="font-weight: bold;">Eq.1. </span> Differential equation of cell population</p> |
− | <p class="normal_text">The equations above describe how | + | <p class="normal_text">The equations above describe how each cell grows in the culture. |
− | Equations (1-1), (1-2) and (1-3) describe the populations of Snow White, the Queen and the Prince. (1-3) is described by the logistic growth equation, but (1-1) and (1-2) are represented by the growth inhibition by MazF dimers. | + | Equations (1-1), (1-2) and (1-3) describe the populations of Snow White <span style ="font-style : italic">coli</span>, the Queen <span style ="font-style : italic">coli</span> and the Prince <span style ="font-style : italic">coli</span>. (1-3) is described by the logistic growth equation, but (1-1) and (1-2) are represented by the growth inhibition by MazF dimers. |
− | This factor is designed so that its value is small when the concentration of MazF dimers is | + | This factor is designed so that its value is small when the concentration of MazF dimers is high, and its value converges to 1 when the concentration of MazF dimers is low.</p> |
</li><!-- /1.1. Cell Population --> | </li><!-- /1.1. Cell Population --> | ||
− | <li><h2>2. | + | <li><h2>2. The <span style ="font-style : italic">mazEF</span> system</h2> |
<ul id="modeling_maz_system" class="non_dotted_list"> | <ul id="modeling_maz_system" class="non_dotted_list"> | ||
− | <li><h3>2.1. Expression of | + | <li><h3>2.1. Expression of the <span style ="font-style : italic">mazEF</span> system</h3> |
− | <p class="normal_text">After translation, MazE and MazF each form | + | <p class="normal_text">After translation, MazE and MazF each form a dimer which can be activated to exert its function.<div style="text-align: center;"></p> |
− | <a href="https://static.igem.org/mediawiki/2016/8/88/T--Tokyo_Tech--Model_Details_2.png"><img src="https://static.igem.org/mediawiki/2016/8/88/T--Tokyo_Tech--Model_Details_2.png" /></a><br /> | + | <a href="https://static.igem.org/mediawiki/2016/8/88/T--Tokyo_Tech--Model_Details_2.png"><img src="https://static.igem.org/mediawiki/2016/8/88/T--Tokyo_Tech--Model_Details_2.png" style="width: 600px;"/></a><br /> |
− | <a href="https://static.igem.org/mediawiki/2016/c/c3/T--Tokyo_Tech--Model_Details_3.png"><img src="https://static.igem.org/mediawiki/2016/c/c3/T--Tokyo_Tech--Model_Details_3.png" /></a> | + | <a href="https://static.igem.org/mediawiki/2016/c/c3/T--Tokyo_Tech--Model_Details_3.png"><img src="https://static.igem.org/mediawiki/2016/c/c3/T--Tokyo_Tech--Model_Details_3.png" style="width: 600px;"/></a> |
− | <p class="normal_text">Two | + | <p class="normal_text">Two MazF dimers sandwich a MazE dimer, forming MazF2-MazE2-MazF2 heterohexamers and suppressing the toxicity of the MazF dimers.</p> |
− | <a href="https://static.igem.org/mediawiki/2016/e/ea/T--Tokyo_Tech--Model_Details_4.png"><img src="https://static.igem.org/mediawiki/2016/e/ea/T--Tokyo_Tech--Model_Details_4.png" /></a> | + | <a href="https://static.igem.org/mediawiki/2016/e/ea/T--Tokyo_Tech--Model_Details_4.png"><img src="https://static.igem.org/mediawiki/2016/e/ea/T--Tokyo_Tech--Model_Details_4.png" style="width: 700px;"/></a> |
− | <a href="https://static.igem.org/mediawiki/2016/3/32/T--Tokyo_Tech--Model_Details_5.png"><img src="https://static.igem.org/mediawiki/2016/3/32/T--Tokyo_Tech--Model_Details_5.png" style="width: | + | <a href="https://static.igem.org/mediawiki/2016/3/32/T--Tokyo_Tech--Model_Details_5.png"><img src="https://static.igem.org/mediawiki/2016/3/32/T--Tokyo_Tech--Model_Details_5.png" style="width: 800px;" /></a> |
− | <p class="caption"><span style="font-weight: bold">Fig. | + | <p class="caption"><span style="font-weight: bold">Fig.5-5-2. Reaction of the <span style ="font-style : italic">mazEF</span> system</span></p></div> |
− | <p class="normal_text">The mRNAs of Snow White and the Queen decrease | + | <p class="normal_text">The mRNAs of Snow White <span style ="font-style : italic">coli</span> and the Queen <span style ="font-style : italic">coli</span> decrease because of their original degradation and the cleavage at ACA sequences by MazF dimers.<br>Applying mass action kinetic laws, we obtain the following set of differential equations.</p> |
− | + | ||
<h3>Snow White</h3> | <h3>Snow White</h3> | ||
− | <p>$$ | + | <p>$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ |
− | \frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ | + | |
- d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$<br />$$ \tag{2-1} $$</p> | - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$<br />$$ \tag{2-1} $$</p> | ||
<p>$$ \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] $$ <br /> | <p>$$ \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] $$ <br /> | ||
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+ k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE]$$ <br />$$\tag{2-13} $$</p> | + k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE]$$ <br />$$\tag{2-13} $$</p> | ||
<p>$$\frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa]$$ <br />$$ \tag{2-14}$$</p> | <p>$$\frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa]$$ <br />$$ \tag{2-14}$$</p> | ||
− | <p class="caption"><span style="font-weight: bold">Eq. 2. </span>Differential | + | <p class="caption"><span style="font-weight: bold">Eq. 2. </span>Differential equations of the <span style ="font-style : italic">mazEF</span> system</p> |
− | <p class="normal_text">Equations (2-1) and (2-8) describe the concentration of mRNAs under | + | <p class="normal_text">Equations (2-1) and (2-8) describe the concentration of mRNAs under AHL-inducible promoters. Thus, they comprise terms of production by leaky expression of promoters, terms of production by Hill function dependent on the concentration of C4HSL (C4) and 3OC12HSL (C12), terms of original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers.<br> |
− | + | Since equations (2-2), (2-3), (2-5), (2-6), (2-7), (2-9), (2-10), (2-12), (2-13) and (2-14) describe the concentrations of complexes, mainly they comprise terms of production and terms of binding and dissociation.</p> | |
− | + | </li><!-- /1.2.1. Expression of the <span style ="font-style : italic">mazEF</span> system --> | |
− | </li><!-- /1.2.1. Expression of | + | |
<li><h3>2.2. Cleavage by MazF dimers</h3> | <li><h3>2.2. Cleavage by MazF dimers</h3> | ||
− | <p class="normal_text">MazF dimers recognize and cleave | + | <p class="normal_text">MazF dimers recognize and cleave ACA sequences in mRNAs, thus acting as a toxin.We estimated the rate of recognitions of ACA sequences by MazF dimers at $$ 1-(1-f)^n $$ where n is the number of ACA sequences in mRNA and f is the probability of distinction of ACA sequences on each mRNA. Then, we expressed the rate of degradation by MazF dimers in $$ F(1-(1-f)^{f_{mRNA}}) $$ and obtain the following set of differential equations.</p> |
− | + | ||
− | + | ||
<h3>Snow White</h3> | <h3>Snow White</h3> | ||
<p>$$\frac{d[mRNA_{RFP}]}{dt} = k - d[mRNA_{RFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{RFP}}})[mRNA_{RFP}][DiMazF] | <p>$$\frac{d[mRNA_{RFP}]}{dt} = k - d[mRNA_{RFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{RFP}}})[mRNA_{RFP}][DiMazF] | ||
$$ <br />$$ \tag{3-1} $$</p> | $$ <br />$$ \tag{3-1} $$</p> | ||
− | <p>$$ | + | <p>$$\frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}$$ |
− | \frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}$$ | + | |
<br />$$ \tag{3-2} $$</p> | <br />$$ \tag{3-2} $$</p> | ||
<p>$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ | <p>$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ | ||
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<h3>Queen</h3> | <h3>Queen</h3> | ||
<p>$$\frac{d[mRNA_{GFP}]}{dt} = k - d[mRNA_{GFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{GFP}}})[mRNA_{GFP}][DiMazF] | <p>$$\frac{d[mRNA_{GFP}]}{dt} = k - d[mRNA_{GFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{GFP}}})[mRNA_{GFP}][DiMazF] | ||
− | $$<br />$$ \tag{3-5} | + | $$<br />$$ \tag{3-5} $$</p> |
<p>$$ | <p>$$ | ||
\frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} \\ | \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} \\ | ||
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<p>$$\frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF]$$ | <p>$$\frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF]$$ | ||
<br />$$ \tag{3-8} $$</p> | <br />$$ \tag{3-8} $$</p> | ||
− | <p class="caption"><span style="font-weight: bold">Eq. 3. </span>Differential | + | <p class="caption"><span style="font-weight: bold">Eq. 3. </span>Differential equations of mRNA concentrations</p> |
− | <p class="normal_text">The equations above comprise terms of production, terms of original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers. | + | <p class="normal_text">The equations above comprise terms of production, terms of only original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers. |
</p> | </p> | ||
</li><!-- /1.2.2. Cleavage by MazF dimers --> | </li><!-- /1.2.2. Cleavage by MazF dimers --> | ||
</ul><!-- /modeling_maz_system --> | </ul><!-- /modeling_maz_system --> | ||
− | </li><!-- /1.2. Maz | + | </li><!-- /1.2. the Maz system --> |
− | <li><h2>3. | + | <li><h2>3. Signaling molecules</h2> |
− | <a href="https://static.igem.org/mediawiki/2016/c/c4/T--Tokyo_Tech--Model_Details_6.png"><img src="https://static.igem.org/mediawiki/2016/c/c4/T--Tokyo_Tech--Model_Details_6.png" style="width: | + | <div style="text-align: center;"><a href="https://static.igem.org/mediawiki/2016/c/c4/T--Tokyo_Tech--Model_Details_6.png"><img src="https://static.igem.org/mediawiki/2016/c/c4/T--Tokyo_Tech--Model_Details_6.png" style="width: 800px;" /></a> |
− | <p class="caption"><span style="font-weight:bold;">Fig. | + | <p class="caption"><span style="font-weight:bold;">Fig.5-5-3. Reaction of signaling molecules</span></p></div> |
− | <p class="normal_text">Snow White expresses RhlI under Plux induced by C12, the Queen expresses LasI under Prhl induced by C4 and the Prince expresses AmiE under Plux induced by C12.< | + | <p class="normal_text">Snow White <span style ="font-style : italic">coli</span> expresses RhlI under Plux induced by C12, the Queen <span style ="font-style : italic">coli</span> expresses LasI under Prhl induced by C4 and the Prince <span style ="font-style : italic">coli</span> expresses AmiE under Plux induced by C12.<br> |
− | + | The mRNAs of Snow White <span style ="font-style : italic">coli</span> and the Queen <span style ="font-style : italic">coli</span> decrease from original degradation and the cleavage at ACA sequences by MazF dimers. On the other hand, those of the Prince <span style ="font-style : italic">coli</span> don’t have any MazF genes so they decrease from original degradation only.<br> | |
− | + | After translation, C4 and C12 are enzymatically synthesized by LasI and RhlI from some substrates respectively.<br> | |
− | + | For simplicity, we assumed that the amount of substrates is sufficient so that the C4 and C12 synthesis rate per cell is estimated to be proportional to the LasI and RhlI concentrations.C4 decreases from original degradation only meanwhile C12 decreases from both original degradation and degradation by AmiE, which the Prince <span style ="font-style : italic">coli</span> produces.<br> | |
− | + | Applying mass action kinetic laws, we obtain the following set of differential equations.</p> | |
− | + | ||
− | + | ||
<p>$$ \frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}f[mRNA_{RhlI}][DiMazF] $$<br />$$\tag{4-1}$$</p> | <p>$$ \frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}f[mRNA_{RhlI}][DiMazF] $$<br />$$\tag{4-1}$$</p> | ||
<p>$$\frac{d[RhlI]}{dt} = \alpha [mRNA_{RhlI}] - d_{RhlI}[RhlI] \tag{4-2}$$</p> | <p>$$\frac{d[RhlI]}{dt} = \alpha [mRNA_{RhlI}] - d_{RhlI}[RhlI] \tag{4-2}$$</p> | ||
− | <p>$$ \frac{d[ | + | <p>$$ \frac{d[C4]}{dt} = p_{Rhl}[RhlI]P_{Snowwhite} - d_{C4}[C4] \tag{4-3} $$</p> |
<p>$$ \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} - d[mRNA_{LasI}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{LasI}}})[mRNA_{LasI}][DiMazF] $$<br />$$\tag{4-4}$$</p> | <p>$$ \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} - d[mRNA_{LasI}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{LasI}}})[mRNA_{LasI}][DiMazF] $$<br />$$\tag{4-4}$$</p> | ||
<p>$$\frac{d[LasI]}{dt} = \alpha [mRNA_{LasI}] - d_{LasI}[LasI] \tag{4-5}$$</p> | <p>$$\frac{d[LasI]}{dt} = \alpha [mRNA_{LasI}] - d_{LasI}[LasI] \tag{4-5}$$</p> | ||
− | <p>$$\frac{d[ | + | <p>$$\frac{d[C12]}{dt} = p_{C12}[LasI]P_{Stepmother} - d_{C12}[C12] - D[C12][AmiE]$$ <br /> $$\tag{4-6}$$</p> |
− | <p>$$\frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^ | + | <p>$$\frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{AmiE}]$$ <br />$$\tag{4-7}$$</p> |
<p>$$\frac{d[AmiE]}{dt} = \alpha [mRNA_{AmiE}]P_{Prince} - d_{AmiE}[AmiE] \tag{4-8} $$</p> | <p>$$\frac{d[AmiE]}{dt} = \alpha [mRNA_{AmiE}]P_{Prince} - d_{AmiE}[AmiE] \tag{4-8} $$</p> | ||
− | + | ||
− | <p class="caption"><span style="font-weight: bold;">Eq. 4. </span> Differential | + | <p class="caption"><span style="font-weight: bold;">Eq. 4. </span> Differential equations of signaling molecules</p> |
− | + | ||
− | <p class="normal_text">Equations (4-1), (4-4) and (4-7) describe the concentrations of mRNAs under the AHL | + | <p class="normal_text">Equations (4-1), (4-4) and (4-7) describe the concentrations of mRNAs under the AHL-inducible promoters.Thus, they comprise terms of production by leaky expression of promoters, terms of production by Hill function depending on the concentration of C4 and C12, terms of original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers.<br> |
− | + | The other ODEs describe how the concentrations of materials change in individuals, on the other hand (4-3), (4-6) describe the concentrations of C4 and C12 in the whole culture medium.</p> | |
− | + | ||
</li> | </li> | ||
</ul><!-- /modeling_maz_list --> | </ul><!-- /modeling_maz_list --> | ||
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</div> | </div> | ||
</div><!-- /modeling_maz_system --> | </div><!-- /modeling_maz_system --> | ||
− | + | ||
− | <!-- /UNTIL HERE | + | <!-- /UNTIL HERE the Maz system --> |
− | + | ||
− | + | ||
<div id="parameter_discriptions" class="container"> | <div id="parameter_discriptions" class="container"> | ||
<div id="parameter_discription_header" class="container_header"> | <div id="parameter_discription_header" class="container_header"> | ||
<h2><span>Parameters</span></h2> | <h2><span>Parameters</span></h2> | ||
</div><!-- /parameter_discription_header --> | </div><!-- /parameter_discription_header --> | ||
− | + | ||
<!-- この辺から表 --> | <!-- この辺から表 --> | ||
<div id="parameter_discription_contents" class="container_contents"> | <div id="parameter_discription_contents" class="container_contents"> | ||
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<tr> | <tr> | ||
<td>$$ g $$</td> | <td>$$ g $$</td> | ||
− | <td>0.0123</td> | + | <td>$$ 0.0123 $$</td> |
<td>Growth rate of each cells</td> | <td>Growth rate of each cells</td> | ||
− | <td>Fitted to experimental data</td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model#population">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ P_{max} $$</td> | <td>$$ P_{max} $$</td> | ||
− | <td>3. | + | <td>$$3.3 $$</td> |
<td>Carrying capacity</td> | <td>Carrying capacity</td> | ||
− | <td>Fitted to experimental data</td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model#population">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 445: | Line 437: | ||
<td>$$ 0.462234 nM^{-1} min^{-1} $$ </td> | <td>$$ 0.462234 nM^{-1} min^{-1} $$ </td> | ||
<td>Effect of MazF dimer on growth rate of each cells</td> | <td>Effect of MazF dimer on growth rate of each cells</td> | ||
− | <td>Fitted to experimental data</td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model#population">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 457: | Line 449: | ||
<td>$$ 2.26 min^{-1} $$</td> | <td>$$ 2.26 min^{-1} $$</td> | ||
<td>Leakage of Plux</td> | <td>Leakage of Plux</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 463: | Line 455: | ||
<td>$$ 4.654 min^{-1} $$</td> | <td>$$ 4.654 min^{-1} $$</td> | ||
<td>Leakage of Prhl</td> | <td>Leakage of Prhl</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 469: | Line 461: | ||
<td>$$ 6.984 nM^{-1} min^{-1} $$ </td> | <td>$$ 6.984 nM^{-1} min^{-1} $$ </td> | ||
<td>Maximum transcription rate of under streams of Plux</td> | <td>Maximum transcription rate of under streams of Plux</td> | ||
− | <td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 475: | Line 467: | ||
<td>$$ 14.95 nM^{-1} min^{-1} $$ </td> | <td>$$ 14.95 nM^{-1} min^{-1} $$ </td> | ||
<td>Maximum transcription rate of understreams of Prhl</td> | <td>Maximum transcription rate of understreams of Prhl</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ n_{Lux} $$</td> | <td>$$ n_{Lux} $$</td> | ||
− | <td> 0.76 </td> | + | <td>$$ 0.76 $$</td> |
<td>Hill coefficient for Plux</td> | <td>Hill coefficient for Plux</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ n_{Rhl} $$</td> | <td>$$ n_{Rhl} $$</td> | ||
− | <td> 5 </td> | + | <td>$$ 5 $$</td> |
<td>Hill cofficient for Prhl</td> | <td>Hill cofficient for Prhl</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 493: | Line 485: | ||
<td>$$ 116.24nM $$</td> | <td>$$ 116.24nM $$</td> | ||
<td>Lumped parameter for the Lux system</td> | <td>Lumped parameter for the Lux system</td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 499: | Line 491: | ||
<td>$$ 1000 nM $$</td> | <td>$$ 1000 nM $$</td> | ||
<td>Lumped parameter for the Rhl system</td> | <td>Lumped parameter for the Rhl system</td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #more">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 505: | Line 497: | ||
<td> $$ 5 nM^{-1} min^{-1} $$</td> | <td> $$ 5 nM^{-1} min^{-1} $$</td> | ||
<td>Cutting rate at ACA sequences on mRNA by MazF dimers </td> | <td>Cutting rate at ACA sequences on mRNA by MazF dimers </td> | ||
− | <td> | + | <td> Assumption </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f $$</td> | <td>$$ f $$</td> | ||
− | <td> 0.299 </td> | + | <td>$$ 0.299 $$</td> |
<td>The probability of distinction of ACA sequences on each mRNA</td> | <td>The probability of distinction of ACA sequences on each mRNA</td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{RFP}} $$</td> | <td>$$ f_{mRNA_{RFP}} $$</td> | ||
− | <td> 10 </td> | + | <td>$$ 10 $$</td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{RFP}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{GFP}} $$</td> | <td>$$ f_{mRNA_{GFP}} $$</td> | ||
− | <td> 23 </td> | + | <td>$$ 23 $$</td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{GFP}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{RhlI}} $$</td> | <td>$$ f_{mRNA_{RhlI}} $$</td> | ||
− | <td> 1 </td> | + | <td>$$ 1 $$</td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{RhlI}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{LasI}} $$</td> | <td>$$ f_{mRNA_{LasI}} $$</td> | ||
− | <td> 10 </td> | + | <td>$$ 10 $$</td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{LasI}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{MazF}} $$</td> | <td>$$ f_{mRNA_{MazF}} $$</td> | ||
− | <td> 2 </td> | + | <td> $$2$$ </td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{MazF}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ f_{mRNA_{MazE}} $$</td> | <td>$$ f_{mRNA_{MazE}} $$</td> | ||
− | <td> 2 </td> | + | <td> $$2$$ </td> |
− | <td> | + | <td>The number of ACA sequences on mRNA_{MazE}</td> |
<td> Extraction of data </td> | <td> Extraction of data </td> | ||
</tr> | </tr> | ||
Line 553: | Line 545: | ||
<td> $$ 0.04 min_{-1} $$ </td> | <td> $$ 0.04 min_{-1} $$ </td> | ||
<td>Translation rate of </td> | <td>Translation rate of </td> | ||
− | <td> | + | <td> Assumption </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 559: | Line 551: | ||
<td> $$ 6.82 nM_{-1} min_{-1} $$ </td> | <td> $$ 6.82 nM_{-1} min_{-1} $$ </td> | ||
<td>Formation rate of MazF dimer </td> | <td>Formation rate of MazF dimer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a> </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 565: | Line 557: | ||
<td> $$ 6.24 nM^{-1} min^{-1} $$ </td> | <td> $$ 6.24 nM^{-1} min^{-1} $$ </td> | ||
<td>Formation rate of MazF dimer </td> | <td>Formation rate of MazF dimer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 571: | Line 563: | ||
<td> $$ 3.46 nM^{-1} min^{-1} $$ </td> | <td> $$ 3.46 nM^{-1} min^{-1} $$ </td> | ||
<td>Formation rate of MazF dimer </td> | <td>Formation rate of MazF dimer </td> | ||
− | <td> Fitted to experimental data | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 577: | Line 569: | ||
<td> $$ 7.25 min^{-1} $$ </td> | <td> $$ 7.25 min^{-1} $$ </td> | ||
<td>Dissociation rate of MazF dimer </td> | <td>Dissociation rate of MazF dimer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 583: | Line 575: | ||
<td> $$ 4.51 nM^{-1} min^{-1} $$ </td> | <td> $$ 4.51 nM^{-1} min^{-1} $$ </td> | ||
<td>Formation rate of Maz hexamer </td> | <td>Formation rate of Maz hexamer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 589: | Line 581: | ||
<td> $$ 4.05 min^{-1} $$ </td> | <td> $$ 4.05 min^{-1} $$ </td> | ||
<td>Dissociation rate of Maz hexamer </td> | <td>Dissociation rate of Maz hexamer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 595: | Line 587: | ||
<td> $$ 0.07 min^{-1} $$ </td> | <td> $$ 0.07 min^{-1} $$ </td> | ||
<td> Production rate of C4HSL by RhlI </td> | <td> Production rate of C4HSL by RhlI </td> | ||
− | <td> | + | <td> Assumption </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
Line 601: | Line 593: | ||
<td> $$ 0.07 min^{-1} $$ </td> | <td> $$ 0.07 min^{-1} $$ </td> | ||
<td> Production rate of 3OC12HSL by LasI </td> | <td> Production rate of 3OC12HSL by LasI </td> | ||
− | <td> | + | <td> Assumption </td> |
</tr> | </tr> | ||
<tr> | <tr> | ||
<td>$$ D $$</td> | <td>$$ D $$</td> | ||
− | <td> $$ | + | <td> $$ 0.1 nM^{-1} min^{-1} $$ </td> |
<td> Decomposition rate of 3OC12HSL by AmiE </td> | <td> Decomposition rate of 3OC12HSL by AmiE </td> | ||
− | <td> | + | <td> Assumption </td> |
− | </tr> | + | </tr> |
<tr> | <tr> | ||
<td>$$ d $$</td> | <td>$$ d $$</td> | ||
Line 617: | Line 609: | ||
<tr> | <tr> | ||
<td>$$ d_{RFP} $$</td> | <td>$$ d_{RFP} $$</td> | ||
− | <td>$$ 0. | + | <td>$$ 0.005 min^{-1} $$ </td> |
<td> Degradation rate of RFP </td> | <td> Degradation rate of RFP </td> | ||
− | <td> | + | <td> Assumption </td> |
</td> | </td> | ||
<tr> | <tr> | ||
<td>$$ d_{GFP} $$</td> | <td>$$ d_{GFP} $$</td> | ||
− | <td>$$ 0. | + | <td>$$ 0.005 min^{-1} $$ </td> |
<td> Degradation rate of GFP </td> | <td> Degradation rate of GFP </td> | ||
− | <td> | + | <td> Assumption </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 631: | Line 623: | ||
<td>$$ 0.0167 min^{-1} $$ </td> | <td>$$ 0.0167 min^{-1} $$ </td> | ||
<td> Degradation rate of RhlI </td> | <td> Degradation rate of RhlI </td> | ||
− | <td> Leference<a href ="#references">1] </td> | + | <td> Leference<a href ="#references">[1] </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 643: | Line 635: | ||
<td>$$ 0.7 min^{-1} $$ </td> | <td>$$ 0.7 min^{-1} $$ </td> | ||
<td> Degradation rate of MazF </td> | <td> Degradation rate of MazF </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 649: | Line 641: | ||
<td>$$ 0.17 min^{-1} $$ </td> | <td>$$ 0.17 min^{-1} $$ </td> | ||
<td> Degradation rate of MazF dimer </td> | <td> Degradation rate of MazF dimer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a> </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 655: | Line 647: | ||
<td>$$ 0.55 min^{-1} $$ </td> | <td>$$ 0.55 min^{-1} $$ </td> | ||
<td> Degradation rate of MazE </td> | <td> Degradation rate of MazE </td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a> </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 661: | Line 653: | ||
<td>$$ 0.416 min^{-1} $$ </td> | <td>$$ 0.416 min^{-1} $$ </td> | ||
<td> Degradation rate of MazE dimer </td> | <td> Degradation rate of MazE dimer </td> | ||
− | <td> Fitted to experimental data </td> | + | <td> <a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a> </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 667: | Line 659: | ||
<td>$$ 0.511 min^{-1} $$ </td> | <td>$$ 0.511 min^{-1} $$ </td> | ||
<td> Degradation rate of Maz hexameter </td> | <td> Degradation rate of Maz hexameter </td> | ||
− | <td> Fitted to experimental data </td> | + | <td><a href="https://2016.igem.org/Team:Tokyo_Tech/Model #toxin">Fitted to experimental data</a></td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 673: | Line 665: | ||
<td>$$ 0.000222 min^{-1} $$ </td> | <td>$$ 0.000222 min^{-1} $$ </td> | ||
<td> Degradation rate of C4HSL </td> | <td> Degradation rate of C4HSL </td> | ||
− | <td> Literature<a href ="#references">[ | + | <td> Literature<a href ="#references">[3] </td> |
</td> | </td> | ||
<tr> | <tr> | ||
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<td>$$ 0.004 min^{-1} $$ </td> | <td>$$ 0.004 min^{-1} $$ </td> | ||
<td> Degradation rate of 3OC12HSL </td> | <td> Degradation rate of 3OC12HSL </td> | ||
− | <td> Literature<a href ="#references">[ | + | <td> Literature<a href ="#references">[4] </td> |
</td> | </td> | ||
<tr> | <tr> | ||
Line 690: | Line 682: | ||
</table> | </table> | ||
</div><!-- /parameter_discription_contents --> | </div><!-- /parameter_discription_contents --> | ||
− | + | ||
<!-- この辺まで表 --> | <!-- この辺まで表 --> | ||
<div class="back_link contents"> | <div class="back_link contents"> | ||
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</div> | </div> | ||
</div><!-- /parameter_discriptions --> | </div><!-- /parameter_discriptions --> | ||
− | + | ||
<div id="references" class="container container_bottom"> | <div id="references" class="container container_bottom"> | ||
<div id="references_header" class="container_header"> | <div id="references_header" class="container_header"> | ||
Line 704: | Line 696: | ||
<p class="normal_text"> [1] <a href="https://2014.igem.org/Team:ETH_Zurich" target="_blank">https://2014.igem.org/Team:ETH_Zurich</a></p> | <p class="normal_text"> [1] <a href="https://2014.igem.org/Team:ETH_Zurich" target="_blank">https://2014.igem.org/Team:ETH_Zurich</a></p> | ||
<p class="normal_text"> [2] <a href="http://www.ncbi.nlm.nih.gov/pubmed/10329160" target="_blank">http://www.ncbi.nlm.nih.gov/pubmed/10329160</a></p> | <p class="normal_text"> [2] <a href="http://www.ncbi.nlm.nih.gov/pubmed/10329160" target="_blank">http://www.ncbi.nlm.nih.gov/pubmed/10329160</a></p> | ||
− | <p class="normal_text"> [3 | + | <p class="normal_text"> [3] <a href="https://www.ncbi.nlm.nih.gov/pubmed/19584835" target="_blank">https://www.ncbi.nlm.nih.gov/pubmed/19584835</a></p> |
− | + | <p class="normal_text"> [4] <a href="https://2015.igem.org/Team:Technion_HS_Israel" target="_blank">https://2015.igem.org/Team:Technion_HS_Israel</a></p> | |
− | <p class="normal_text"> [ | + | |
</div><!-- /references_contents --> | </div><!-- /references_contents --> | ||
</div><!-- /references --> | </div><!-- /references --> |
Latest revision as of 00:46, 20 October 2016
Detailed description
Model development
To simulate the cell-cell communication system, we developed an ordinary differential equation model. The following segments describe in detail how the equations were developed with the mazEF system.
Differencial equations
Snow White
\begin{equation} \frac{d[mRNA_{RFP}]}{dt} = k - d[mRNA_{RFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{RFP}}})[mRNA_{RFP}][DiMazF] \end{equation} \begin{equation} \frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}f[mRNA_{RhlI}][DiMazF] \end{equation} \begin{equation} \frac{d[RFP]}{dt} = \alpha [mRNA_{RFP}] - d_{RFP}[RFP] \end{equation} \begin{equation} \frac{d[RhlI]}{dt} = \alpha [mRNA_{RhlI}] - d_{RhlI}[RhlI] \end{equation} \begin{equation} \frac{d[C4]}{dt} = p_{C4}[RhlI]P_{Snow White} - d_{C4}[C4] \end{equation} \begin{equation} \frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] \end{equation} \begin{equation} \frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF] \end{equation} \begin{equation} \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] \end{equation} \begin{equation} \frac{d[DiMazF]}{dt} = k_{DiMazF}[MazF] - k_{-DiMazF}[DiMazF] - 2k_{Hexa}[DiMazE][DiMazF]^2 \\ + 2k_{-Hexa}[MazHexamer] - d_{DiMazF}[DiMazF] \end{equation} \begin{equation} \frac{d[MazE]}{dt} = \alpha [mRNA_{MazE}] - 2k_{DiMazE}[MazE] + 2k_{-DiMazE}[DiMazE] - d_{MazE}[MazE] \end{equation} \begin{equation} \frac{d[DiMazE]}{dt} = k_{DiMazE}[MazE] - k_{-DiMazE}[DiMazE] - k_{Hexa}[DiMazE][DiMazF]^2 \\ + k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE] \end{equation} \begin{equation} \frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa] \end{equation} \begin{equation} \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} \end{equation}Queen
\begin{equation} \frac{d[mRNA_{GFP}]}{dt} = k - d[mRNA_{GFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{GFP}}})[mRNA_{GFP}][DiMazF] \end{equation} \begin{equation} \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} \\ - d[mRNA_{LasI}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{LasI}}})[mRNA_{LasI}][DiMazF] \end{equation} \begin{equation} \frac{d[GFP]}{dt} = \alpha [mRNA_{GFP}] - d_{GFP}[GFP] \end{equation} \begin{equation} \frac{d[LasI]}{dt} = \alpha [mRNA_{LasI}] - d_{LasI}[LasI] \end{equation} \begin{equation} \frac{d[C12]}{dt} = p_{C12}[LasI]P_{Queen} - d_{C12}[C12] - D[C12][AmiE] \end{equation} \begin{equation} \frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] \end{equation} \begin{equation} \frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF] \end{equation} \begin{equation} \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] \end{equation} \begin{equation} \frac{d[DiMazF]}{dt} = k_{DiMazF}[MazF] - k_{-DiMazF}[DiMazF] - 2k_{Hexa}[DiMazE][DiMazF]^2 \\ + 2k_{-Hexa}[MazHexamer] - d_{DiMazF}[DiMazF] \end{equation} \begin{equation} \frac{d[MazE]}{dt} = \alpha [mRNA_{MazE}] - 2k_{DiMazE}[MazE] + 2k_{-DiMazE}[DiMazE] - d_{MazE}[MazE] \end{equation} \begin{equation} \frac{d[DiMazE]}{dt} = k_{DiMazE}[MazE] - k_{-DiMazE}[DiMazE] - k_{Hexa}[DiMazE][DiMazF]^2 \\ + k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE] \end{equation} \begin{equation} \frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa] \end{equation} \begin{equation} \frac{dP_{Queen}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Queen}\\ \end{equation}Prince
\begin{equation} \frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{AmiE}] \end{equation} \begin{equation} \frac{d[AmiE]}{dt} = \alpha [mRNA_{AmiE}]P_{Prince} - d_{AmiE}[AmiE] \end{equation} \begin{equation} \frac{dP_{Prince}}{dt} = g\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Prince} \end{equation}Explanation about parameters
Parameter | Description |
$$g$$ | Growth rate of each cells |
$$P_{max}$$ | Carrying capacity |
$$E_{DiMazF}$$ | Effect of MazF dimer on growth rate |
$$k$$ | Transcription rate of downstream of Pcon |
$$leak_{Plux}$$ | Leakage of Plux |
$$leak_{Prhl}$$ | Leakage of Prhl |
$$\kappa_{Lux}$$ | Maximum transcription rate of mRNA under Plux |
$$\kappa_{Rhl}$$ | Maximum transcription rate of downstream of Prhl |
$$n_{Lux}$$ | Hill coefficient for Plux |
$$n_{Rhl}$$ | Hill coefficient for Prhl |
$$K_{mLux}$$ | Lumped paremeter for the Lux System |
$$K_{mRhl}$$ | Lumped paremeter for the Rhl System |
$$F_{DiMazF}$$ | Cutting rate at ACA sequences on mRNA by MazF dimer |
$$f$$ | The probability of distinction of ACA sequencess in each mRNA |
$$f_{mRNA_{RFP}}$$ | The number of ACA sequences in \(mRNA_{RFP}\) |
$$f_{mRNA_{GFP}}$$ | The number of ACA sequences in \(mRNA_{GFP}\) |
$$f_{mRNA_{RhlI}}$$ | The number of ACA sequences in \(mRNA_{RhlI}\) |
$$f_{mRNA_{LasI}}$$ | The number of ACA sequences in \(mRNA_{LasI}\) |
$$f_{mRNA_{MazF}}$$ | The number of ACA sequences in \(mRNA_{MazF}\) |
$$f_{mRNA_{MazE}}$$ | The number of ACA sequences in \(mRNA_{MazE}\) |
$$\alpha$$ | Translation rate of Protein |
$$k_{DiMazF}$$ | Formation rate of MazF dimer |
$$k_{-DiMazF}$$ | Dissociation rate of MazF dimer |
$$k_{DiMazE}$$ | Formation rate of MazE dimer |
$$k_{-DiMazE}$$ | Dissociation rate of MazE dimer |
$$k_{Hexa}$$ | Formation rate of Maz hexamer |
$$k_{-Hexa}$$ | Dissociation rate of Maz hexamer |
$$p_{C4}$$ | Production rate of C4HSL by RhlI |
$$p_{C12}$$ | Production rate of 3OC12HSL by LuxI |
$$D$$ | Decomposition rate of 3OC12HSL by AmiE |
$$d$$ | Degradation rate of mRNA |
$$d_{RFP}$$ | Degradation rate of RFP |
$$d_{GFP}$$ | Degradation rate of GFP |
$$d_{RhlI}$$ | Degradation rate of RhlI |
$$d_{LasI}$$ | Degradation rate of LasI |
$$d_{MazF}$$ | Degradation rate of MazF |
$$d_{DiMazF}$$ | Degradation rate of MazF dimer |
$$d_{MazE}$$ | Degradation rate of MazE |
$$d_{DiMazE}$$ | Degradation rate of MazE dimer |
$$d_{Hexa}$$ | Degradation rate of Maz Hexamer |
$$d_{C4}$$ | Degradation rate of C4HSL |
$$d_{C12}$$ | Degradation rate of 3OC12HSL |
$$d_{AmiE}$$ | Degradation rate of AmiE |
1. Cell population
$$ \frac{dP_{Snow White}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}} \right) P_{Snow White} $$
$$ \tag{1-1} $$$$ \frac{dP_{Queen}}{dt} = g \frac{E_{DiMazF}}{E_{DiMazF}+[DiMazF]}\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Queen}$$
$$ \tag{1-2} $$$$ \frac{dP_{Prince}}{dt} = g\left(1- \frac{P_{Snow White}+P_{Queen}+P_{Prince}}{P_{max}}\right) P_{Prince} \tag{1-3} $$
The equations above describe how each cell grows in the culture. Equations (1-1), (1-2) and (1-3) describe the populations of Snow White coli, the Queen coli and the Prince coli. (1-3) is described by the logistic growth equation, but (1-1) and (1-2) are represented by the growth inhibition by MazF dimers. This factor is designed so that its value is small when the concentration of MazF dimers is high, and its value converges to 1 when the concentration of MazF dimers is low.
2. The mazEF system
2.1. Expression of the mazEF system
After translation, MazE and MazF each form a dimer which can be activated to exert its function.
Two MazF dimers sandwich a MazE dimer, forming MazF2-MazE2-MazF2 heterohexamers and suppressing the toxicity of the MazF dimers.
The mRNAs of Snow White coli and the Queen coli decrease because of their original degradation and the cleavage at ACA sequences by MazF dimers.
Applying mass action kinetic laws, we obtain the following set of differential equations.Snow White
$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$
$$ \tag{2-1} $$$$ \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] $$
$$\tag{2-2}$$$$ \frac{d[DiMazF]}{dt} = k_{DiMazF}[MazF] - k_{-DiMazF}[DiMazF] - 2k_{Hexa}[DiMazE][DiMazF]^2 \\ + 2k_{-Hexa}[MazHexamer] - d_{DiMazF}[DiMazF] $$
$$ \tag{2-3} $$$$ \frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF] $$
$$ \tag{2-4} $$$$\frac{d[MazE]}{dt} = \alpha [mRNA_{MazE}] - 2k_{DiMazE}[MazE] + 2k_{-DiMazE}[DiMazE] - d_{MazE}[MazE]$$
$$\tag{2-5}$$$$ \frac{d[DiMazE]}{dt} = k_{DiMazE}[MazE] - k_{-DiMazE}[DiMazE] - k_{Hexa}[DiMazE][DiMazF]^2 \\ + k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE]$$
$$\tag{2-6} $$$$\frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa]$$
$$ \tag{2-7}$$Queen
$$ \frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$
$$ \tag{2-8} $$$$ \frac{d[MazF]}{dt} = \alpha [mRNA_{MazF}] - 2k_{DiMazF}[MazF] + 2k_{-DiMazF}[DiMazF] - d_{MazF}[MazF] $$
$$\tag{2-9}$$$$ \frac{d[DiMazF]}{dt} = k_{DiMazF}[MazF] - k_{-DiMazF}[DiMazF] - 2k_{Hexa}[DiMazE][DiMazF]^2 \\ + 2k_{-Hexa}[MazHexamer] - d_{DiMazF}[DiMazF] $$
$$ \tag{2-10} $$$$ \frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF] $$
$$ \tag{2-11} $$$$\frac{d[MazE]}{dt} = \alpha [mRNA_{MazE}] - 2k_{DiMazE}[MazE] + 2k_{-DiMazE}[DiMazE] - d_{MazE}[MazE]$$
$$\tag{2-12}$$$$ \frac{d[DiMazE]}{dt} = k_{DiMazE}[MazE] - k_{-DiMazE}[DiMazE] - k_{Hexa}[DiMazE][DiMazF]^2 \\ + k_{-Hexa}[MazHexamer] - d_{DiMazE}[DiMazE]$$
$$\tag{2-13} $$$$\frac{d[MazHexa]}{dt} = k_{Hexa}[DiMazE][DiMazF]^2 - k_{-Hexa}[MazHexa] - d_{Hexa}[MazHexa]$$
$$ \tag{2-14}$$Equations (2-1) and (2-8) describe the concentration of mRNAs under AHL-inducible promoters. Thus, they comprise terms of production by leaky expression of promoters, terms of production by Hill function dependent on the concentration of C4HSL (C4) and 3OC12HSL (C12), terms of original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers.
Since equations (2-2), (2-3), (2-5), (2-6), (2-7), (2-9), (2-10), (2-12), (2-13) and (2-14) describe the concentrations of complexes, mainly they comprise terms of production and terms of binding and dissociation.2.2. Cleavage by MazF dimers
MazF dimers recognize and cleave ACA sequences in mRNAs, thus acting as a toxin.We estimated the rate of recognitions of ACA sequences by MazF dimers at $$ 1-(1-f)^n $$ where n is the number of ACA sequences in mRNA and f is the probability of distinction of ACA sequences on each mRNA. Then, we expressed the rate of degradation by MazF dimers in $$ F(1-(1-f)^{f_{mRNA}}) $$ and obtain the following set of differential equations.
Snow White
$$\frac{d[mRNA_{RFP}]}{dt} = k - d[mRNA_{RFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{RFP}}})[mRNA_{RFP}][DiMazF] $$
$$ \tag{3-1} $$$$\frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}$$
$$ \tag{3-2} $$$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$
$$\tag{3-3}$$$$\frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF]$$
$$ \tag{3-4} $$Queen
$$\frac{d[mRNA_{GFP}]}{dt} = k - d[mRNA_{GFP}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{GFP}}})[mRNA_{GFP}][DiMazF] $$
$$ \tag{3-5} $$$$ \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} \\ - d[mRNA_{LasI}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{LasI}}})[mRNA_{LasI}][DiMazF] $$
$$ \tag{3-6} $$$$\frac{d[mRNA_{MazF}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}}+ [C12]^{n_{Lux}}} \\ - d[mRNA_{MazF}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazF}}})[mRNA_{MazF}][DiMazF] $$
$$\tag{3-7}$$$$\frac{d[mRNA_{MazE}]}{dt} = k - d[mRNA_{MazE}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{MazE}}})[mRNA_{MazE}][DiMazF]$$
$$ \tag{3-8} $$The equations above comprise terms of production, terms of only original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers.
3. Signaling molecules
Snow White coli expresses RhlI under Plux induced by C12, the Queen coli expresses LasI under Prhl induced by C4 and the Prince coli expresses AmiE under Plux induced by C12.
The mRNAs of Snow White coli and the Queen coli decrease from original degradation and the cleavage at ACA sequences by MazF dimers. On the other hand, those of the Prince coli don’t have any MazF genes so they decrease from original degradation only.
After translation, C4 and C12 are enzymatically synthesized by LasI and RhlI from some substrates respectively.
For simplicity, we assumed that the amount of substrates is sufficient so that the C4 and C12 synthesis rate per cell is estimated to be proportional to the LasI and RhlI concentrations.C4 decreases from original degradation only meanwhile C12 decreases from both original degradation and degradation by AmiE, which the Prince coli produces.
Applying mass action kinetic laws, we obtain the following set of differential equations.$$ \frac{d[mRNA_{RhlI}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{RhlI}] - F_{DiMazF}f[mRNA_{RhlI}][DiMazF] $$
$$\tag{4-1}$$$$\frac{d[RhlI]}{dt} = \alpha [mRNA_{RhlI}] - d_{RhlI}[RhlI] \tag{4-2}$$
$$ \frac{d[C4]}{dt} = p_{Rhl}[RhlI]P_{Snowwhite} - d_{C4}[C4] \tag{4-3} $$
$$ \frac{d[mRNA_{LasI}]}{dt} = leak_{Prhl} + \frac{\kappa_{Rhl}[C4]^{n_{Rhl}}}{K_{mRhl}^{n_{Rhl}} + [C4]^{n_{Rhl}}} - d[mRNA_{LasI}] - F_{DiMazF}(1-(1-f)^{f_{mRNA_{LasI}}})[mRNA_{LasI}][DiMazF] $$
$$\tag{4-4}$$$$\frac{d[LasI]}{dt} = \alpha [mRNA_{LasI}] - d_{LasI}[LasI] \tag{4-5}$$
$$\frac{d[C12]}{dt} = p_{C12}[LasI]P_{Stepmother} - d_{C12}[C12] - D[C12][AmiE]$$
$$\tag{4-6}$$$$\frac{d[mRNA_{AmiE}]}{dt} = leak_{Plux} + \frac{\kappa_{Lux}[C12]^{n_{Lux}}}{K_{mLux}^{n_{Lux}} + [C12]^{n_{Lux}}} - d[mRNA_{AmiE}]$$
$$\tag{4-7}$$$$\frac{d[AmiE]}{dt} = \alpha [mRNA_{AmiE}]P_{Prince} - d_{AmiE}[AmiE] \tag{4-8} $$
Equations (4-1), (4-4) and (4-7) describe the concentrations of mRNAs under the AHL-inducible promoters.Thus, they comprise terms of production by leaky expression of promoters, terms of production by Hill function depending on the concentration of C4 and C12, terms of original degradation and terms of degradation from cleavage at ACA sequences by MazF dimers.
The other ODEs describe how the concentrations of materials change in individuals, on the other hand (4-3), (4-6) describe the concentrations of C4 and C12 in the whole culture medium.
Parameters
Parameter | Value | Description | Reference |
---|---|---|---|
$$ g $$ | $$ 0.0123 $$ | Growth rate of each cells | Fitted to experimental data |
$$ P_{max} $$ | $$3.3 $$ | Carrying capacity | Fitted to experimental data |
$$ E_{DiMazF} $$ | $$ 0.462234 nM^{-1} min^{-1} $$ | Effect of MazF dimer on growth rate of each cells | Fitted to experimental data |
$$ k $$ | $$5 min^{-1}$$ | Transcription rate of downstream of Ptet | Reference[1] |
$$ leak_{Plux} $$ | $$ 2.26 min^{-1} $$ | Leakage of Plux | Fitted to experimental data |
$$ leak_{Prhl} $$ | $$ 4.654 min^{-1} $$ | Leakage of Prhl | Fitted to experimental data |
$$ κ_{Lux} $$ | $$ 6.984 nM^{-1} min^{-1} $$ | Maximum transcription rate of under streams of Plux | Fitted to experimental data |
$$ κ_{Rhl} $$ | $$ 14.95 nM^{-1} min^{-1} $$ | Maximum transcription rate of understreams of Prhl | Fitted to experimental data |
$$ n_{Lux} $$ | $$ 0.76 $$ | Hill coefficient for Plux | Fitted to experimental data |
$$ n_{Rhl} $$ | $$ 5 $$ | Hill cofficient for Prhl | Fitted to experimental data |
$$ K_{mLux} $$ | $$ 116.24nM $$ | Lumped parameter for the Lux system | Fitted to experimental data |
$$ K_{mRhl} $$ | $$ 1000 nM $$ | Lumped parameter for the Rhl system | Fitted to experimental data |
$$ F_{DiMazF} $$ | $$ 5 nM^{-1} min^{-1} $$ | Cutting rate at ACA sequences on mRNA by MazF dimers | Assumption |
$$ f $$ | $$ 0.299 $$ | The probability of distinction of ACA sequences on each mRNA | Fitted to experimental data |
$$ f_{mRNA_{RFP}} $$ | $$ 10 $$ | The number of ACA sequences on mRNA_{RFP} | Extraction of data |
$$ f_{mRNA_{GFP}} $$ | $$ 23 $$ | The number of ACA sequences on mRNA_{GFP} | Extraction of data |
$$ f_{mRNA_{RhlI}} $$ | $$ 1 $$ | The number of ACA sequences on mRNA_{RhlI} | Extraction of data |
$$ f_{mRNA_{LasI}} $$ | $$ 10 $$ | The number of ACA sequences on mRNA_{LasI} | Extraction of data |
$$ f_{mRNA_{MazF}} $$ | $$2$$ | The number of ACA sequences on mRNA_{MazF} | Extraction of data |
$$ f_{mRNA_{MazE}} $$ | $$2$$ | The number of ACA sequences on mRNA_{MazE} | Extraction of data |
$$ α $$ | $$ 0.04 min_{-1} $$ | Translation rate of | Assumption |
$$ k_{DiMazF}$$ | $$ 6.82 nM_{-1} min_{-1} $$ | Formation rate of MazF dimer | Fitted to experimental data |
$$ k_{-Di_{MazF}}$$ | $$ 6.24 nM^{-1} min^{-1} $$ | Formation rate of MazF dimer | Fitted to experimental data |
$$ k_{Di_{MazE}}$$ | $$ 3.46 nM^{-1} min^{-1} $$ | Formation rate of MazF dimer | Fitted to experimental data |
$$ k_{-Di_{MazE}}$$ | $$ 7.25 min^{-1} $$ | Dissociation rate of MazF dimer | Fitted to experimental data |
$$ k_{Hexa}$$ | $$ 4.51 nM^{-1} min^{-1} $$ | Formation rate of Maz hexamer | Fitted to experimental data |
$$ k_{-Hexa}$$ | $$ 4.05 min^{-1} $$ | Dissociation rate of Maz hexamer | Fitted to experimental data |
$$ p_{C4}$$ | $$ 0.07 min^{-1} $$ | Production rate of C4HSL by RhlI | Assumption |
$$ p_{C12}$$ | $$ 0.07 min^{-1} $$ | Production rate of 3OC12HSL by LasI | Assumption |
$$ D $$ | $$ 0.1 nM^{-1} min^{-1} $$ | Decomposition rate of 3OC12HSL by AmiE | Assumption |
$$ d $$ | $$ 0.2773 min^{-1} $$ | Degradation rate of mRNA | Leference[2] |
$$ d_{RFP} $$ | $$ 0.005 min^{-1} $$ | Degradation rate of RFP | Assumption |
$$ d_{GFP} $$ | $$ 0.005 min^{-1} $$ | Degradation rate of GFP | Assumption |
$$ d_{RhlI} $$ | $$ 0.0167 min^{-1} $$ | Degradation rate of RhlI | Leference[1] |
$$ d_{LasI} $$ | $$ 0.0167 min^{-1} $$ | Degradation rate of LasI | Leference[1] |
$$ d_{MazF} $$ | $$ 0.7 min^{-1} $$ | Degradation rate of MazF | Fitted to experimental data |
$$ d_{DiMazF} $$ | $$ 0.17 min^{-1} $$ | Degradation rate of MazF dimer | Fitted to experimental data |
$$ d_{MazE} $$ | $$ 0.55 min^{-1} $$ | Degradation rate of MazE | Fitted to experimental data |
$$ d_{DiMazE} $$ | $$ 0.416 min^{-1} $$ | Degradation rate of MazE dimer | Fitted to experimental data |
$$ d_{Hexa} $$ | $$ 0.511 min^{-1} $$ | Degradation rate of Maz hexameter | Fitted to experimental data |
$$ d_{C4} $$ | $$ 0.000222 min^{-1} $$ | Degradation rate of C4HSL | Literature[3] |
$$ d_{C12} $$ | $$ 0.004 min^{-1} $$ | Degradation rate of 3OC12HSL | Literature[4] |
$$ d_{AmiE} $$ | $$ 0.001 min^{-1} $$ | Degradation rate of AmiE | Assumption |