Team:Tokyo Tech/Modeling/Crosstalk Circumvention

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<p style="line-height:0em; text-indent:0em;" name="top">Crosstalk Circumvention Modeling</p>
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<h1>Modeling of Ninja circuit</h1><h2></h2>
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<h1>1. Introduction</h1>
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<h3>1. Introduction
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</h3>
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<h2>
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<p>In order to achieve Signal-dependent state change circuit with crosstalk circumvention, we designed ‘’Ninja circuit’’ which is shown in Fig. 1-1.
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<p> In order to achieve Signal-dependent state change circuit with crosstalk circumvention, we designed "Ninja circuit" (Fig. 4-1-1).
</p>
</p>
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[[Image:Titech2013_modeling_crosstalk_Ninja_circuit.png.png|600px|thumb|center|Fig. 1-1. Our designed ‘’Ninja circuit’’]]
 
<h2>
<h2>
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<p>We analyzed the dynamic characteristics of the whole circuit by modeling Ninja circuit through the modeling of “Ninja” circuit. In addition, we verified how each parameter in the model formula affects the behavior of the circuit.
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[[Image:Titech2013_modeling_crosstalk_Ninja_circuit.png.png|500px|thumb|center|Fig. 4-1-1. Our designed "Ninja circuit"]]
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</h2>
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<h2>
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<p> We analyzed the dynamic characteristics of the whole circuit through the modeling of "Ninja circuit". In addition, we verified how each parameter in the model formula affects the behavior of the circuit.  
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<p>To understand the difference between the original circuit, which cannot prevent from signal crosstalk, and our Ninja model, we compared with two gene circuits on equal terms.
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<p> To understand the difference between our Ninja crosstalk circumvention system and the original circuit, we compared two gene circuits on equal terms.
</p>
</p>
</h2>
</h2>
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<h3>2. Analytical method of dynamic characteristics of the circuit
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</h3>
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<h1>2. Analytical method of dynamic characteristics <br><div align="right">of the circuit</div></h1>
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<h3>
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<h3>2-1. Building a mathematical model</h3>
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2-1. Mathematical model construction
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</h3>
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<h2>
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<p>On the basis of the Hill equation, we built a mathematical model of the Ninja circuit. The mathematical model which was used this time was as below. Value for each parameter will be discussed on Chapter 2.3 .
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<p> On the basis of the Hill equation, we built a mathematical model of the "Ninja circuit". The mathematical model is shown in below. Values for each parameter are discussed on Chapter 2-3.
</p>
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[[Image:Titech2013_modeling_ninjaF1.png|500px|thumb|center|Fig 2.1.1 Equations for our modeling]]
 
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<p>At this time, because of the constant expression of Las and LuxI, we can assume that there are C6 and C12 as input into consideration.
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[[Image:Titech2013_modeling_ninjaF1.png|500px|thumb|center|Fig. 4-1-2. Equations for our modeling]]
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</p>
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<p>Fig2.1.1 is differential equations that describe the changes of C6 and C12. In the circuit we made this time, only degradation of C6 and C12 are considered because they are inputs from the outside.
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</h2>
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[[Image:Titech2013_modeling_ninjaF2.png|500px|thumb|center|Fig 2.1.2 Equation of degradation]]
 
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<p>Fig.2.1.2 is differential equations of LacI. Since we use Promoter TetR that acts as a repressor, the first term shows the suppression of TetR. Although hybrid promoters which express LacI are activated by C6, we have to consider the influence of the crosstalk, which is represented as addition.
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<p> We are going to divide these equations into several groups to explain the mathematical model.
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The first group describes changes of the signaling molecules (Fig. 4-1-3). At this time, because of constant expression of LasR and LuxR, we considered only degradations of 3OC6HSL and 3OC12HSL. They are added as inputs in a pulse manner in this section.
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[[Image:Titech2013_modeling_ninjaF3.png|500px|thumb|center|Fig 2.1.3 Equation of LacI]]
 
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<p>We set a3 as half of a2, because C12 which act as crosstalk is about half of the total,.
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[[Image:Titech2013_modeling_ninjaF2.png|500px|thumb|center|Fig. 4-1-3. Equations of degradations]]
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LacI is not only a hybrid promoter; it is also expressed as one side of the toggle switch. We add a Hill equation to suppress CI. In the end we add expression amount of the leak, then minus the decomposition item of LacI.
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</h2>
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<h2>
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<p>
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Secondly, Fig. 4-1-4 shows differential equation of LacI. Since we used <i>tet</i> promoter (Which is repressed by TetR), the first term shows the suppression of TetR. Although hybrid promoters express LacI as an activation by 3OC6HSL, we had to consider the influence of the crosstalk, which is represented as addition. Because our result from wet experiments shows that the expression level by 3OC12HSL input, which causes crosstalk via LasR activation, is about half of that by 3OC6HSL input, we set a3 value as half of a2 value. About equation (3), not only from the hybrid promoter, LacI is also expressed from one side of the toggle switch. For this expression, we added a Hill equation to show suppression by CI. In the end, we added expression amount of the leak, then minus the decomposition item of LacI.
</p>
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[[Image:Titech2013_modeling_ninjaF4.png|500px|thumb|center|Fig 2.1.4 Equation of CI]]
 
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<p>CI is as same as LacI, which is expressed as one side of the toggle switch. This equation consists of the activation of C12, the repression of LacI, leaky expression and degradation.
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[[Image:Titech2013_modeling_ninjaF3.png|500px|thumb|center|Fig. 4-1-4. The equation of LacI]]
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</h2>
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<h2>
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<p> As the third, CI was expressed not only from <i>las</i> promoter, but also from one side of the toggle switch. As a result, we added a Hill equation (Fig. 4-1-5) to show the suppression by LacI.
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</p>
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</h2>
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<h2>
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[[Image:Titech2013_modeling_ninjaF4.png|500px|thumb|center|Fig. 4-1-5. The equation of CI]]
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</h2>
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<h2>
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<p> Finally, we derived those following equations (Fig. 4-1-6) based on the circuit as well. Mimic indicates the strength of the Mimic state, and Attack indicates the strength of the Attack state.  
</p>
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[[Image:Titech2013_modeling_ninjaF5.png|500px|thumb|center|Fig 2.1.5 Equation of CI434,TetR,GFP,RFP,g2p]]
 
<h2>
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<p>The rest equation of proteins is shown in Fig.2.1.5.
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[[Image:Titech2013_modeling_ninjaF5.png|500px|thumb|center|Fig. 4-1-6. Equations of CI434, TetR, Mimic, Attack, and g2p]]
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</h2>
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<h3>2-2. Descriptions of the parameters</h3>
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<h2>
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<p>Each parameter is defined as the following table (Fig. 4-1-7).
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<h3>2.2 Description of the parameters</h3>
 
<h2>
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<p>Each parameter is defined as the following table.
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[[Image:Titech2013_modeling_ninjaF6.png|700px|thumb|center|Fig. 4-1-7. Descriptions of each parameter]]
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</h2>
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<h3>2-3. Parameter optimization and simulation</h3>
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<h2>
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<p> We carried out the simulation of this time by using MatLab. Since the amount of the parameters of the differential equation was very large, we tried to minimize the amount of the evaluation function (Fig. 4-1-8).
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[[Image:Titech2013_modeling_ninjaF6.png|700px|thumb|center|Fig.2.2.1 Description of each parameter]]
 
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<h3>2.3 Values of the parameters and simulation</h3>
 
<h2>
<h2>
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<p>We carried out the simulation of this time by using MatLab. Since the amount of the parameters of the differential equation is very large, we tried to minimize the amount of the evaluation function. (Fig.2.2.1)
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[[Image:Titech2013_modeling_ninjaF7.png|500px|thumb|center|Fig. 4-1-8. The evaluation function]]
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</h2>
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<h2>
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<p>At time point 0, we added 3OC12HSL. Then 3OC6HSL was added at 300 min. after induction of the Mimic state in toggle switch. If the absolute value of the difference between the integral value of the strength of Attack and Mimic become smaller, we could get the conclusion that toggle switch had high performance. The parameters we explored were a4, a5, and a6. a4 and a5 are maximum expression amounts of LacI and CI in bistable state. a6 and a7 are expression amounts of CI434 and TetR as for crosstalk circumvention. We determined the transfer function of 3OC6HSL-LuxR complex by least squares method fitting from our assay result of Activation of the crosstalk circumvention system circuit by screening the concentration of 3OC6HSL and aTc, which is shown in below (Fig. 4-1-9).
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</p></h2>
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<gallery widths="350px" heights="170px" style="margin-left:auto; margin-right:auto; text-align: left;">
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Image:Titech2013_CrosstalkCircumventionAssay_3-2_5.jpg‎|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-9. Activation of our crosstalk circumvention system circuit</h2>
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Image:Titech2013_modeling_CrosstalkCircumvention_parts_registry.png|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-10. Values used for fitting and the value of transfer function we determined</h2>
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</gallery>
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<h2><p>
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We used values of GFP fluorescence intensity transition of screening the concentration of 3OC6HSL for the fitting. Since the influence <i>lux/tet</i> hybrid promoter gets from TetR is lower when the concentration of aTc is higher, we used values in the case of aTc = 5 µg/mL. Each values of C6 concentration and GFP fluorescence intensity is shown in Fig. 4-1-10. The value "m", the transfer function of 3OC6HSL-LuxR complex, was determined as 2 by the fitting. We used this value as m2 in our model.
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<p>As a result of fitting m2 and exploring the a4, a5, a6, and a7 to minimize the evaluation function (10), we found out that it would be the best selection if we take the parameters as follows (Fig. 4-1-11).
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</h2>
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[[Image:Titech2013_modeling_ninjaF8.png|350px|thumb|center|Fig. 4-1-11. Value of each parameter]]
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[[Image:Titech2013_modeling_ninjaF7.png|700px|thumb|center|Fig.2.3.1 Evaluation function]]
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<h3>2-4. Simulation results and parametric evaluation</h3>
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<em> <h2>Bistability by the toggle switch in "Ninja circuit"</h2> </em>
<h2>
<h2>
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<p>At first we add C12, 300min after induction of the GFP side in toggle switch, C12 is added before the simulation starts. If the absolute value of the difference between the integral value of the expression level of RFP and GFP becomes smaller, we could get the conclusion that toggle switch has high performance. a5 and a6 are two corrections in the maximum expression amount. The graph represents the absolute value of the difference of the area of the red line on the RFP and the green line of GFP. The parameters we are about to explore are a4, a5, which are maximum expression amounts of LacI and CI in bistable state, and a6, a7, which are expression amounts of CI434 and TetR as in prevention of crosstalk.
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<p>We firstly confirmed bistability by toggle switch. In initial state, by pulse addition of 2 nM 3OC12HSL, the CI side got induced and maintained even after decay of 3OC12HSL. After 300 min, with pulse addition of 2 nM 3OC6HSL, the toggle switch starts switching to the Mimic state. In addition, the state was maintained after decay of 3OC12HSL. Thus we could get the conclusion that the Mimic state stays stable after the switching.
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<h3>
 
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2.4 Simulation result and parametric evaluation
 
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</h3>
 
<h2>
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<p>As a result of exploring the a4, a5, a6, a7 to minimize the evaluation function in 2.3, we found out that it would be the best selection if we take the parameters as follows. (Fig.2.3.2)
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[[Image:Titech2013_modeling_ninja1.png|500px|thumb|center|Fig. 4-1-12. Switching from CI to LacI]]
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</h2>
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[[Image:Titech2013_modeling_ninjaF8.png|400px|thumb|center|Fig.2.4.1 Value of each parameter]]
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<h2>
<h2>
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<p>The following graph has been obtained by using the above parameters. In initial state, by the addition of 20nm C12, the CI side get induced、after 300min, with the addition of 20nm C6, the toggle switch starts to switch. We could get the conclusion that the toggle stays stable after the switching.  
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<p>Then, we confirmed the performance of the other side of the toggle switch. First, 2 nM 3OC6HSL was added in a pulse manner, then after 300 min. 3OC12HSL was added in a pulse manner. From following graph (Fig. 4-1-13). in combination with Fig. 4-1-12, we could get the conclusion that the toggle switch shows bistability as we thought.
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</p></h2>
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[[Image:Titech2013_modeling_ninja1.png|700px|thumb|center|Fig.2.4.2 Switching from CI to LacIr]]
 
<h2>
<h2>
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<p>Then, we will confirm the performance of the other side of the toggle switch. First, 20nm C6 was added, then after 300min C12 was added. (Fig.2.4.3) we could got the conclusion that the toggle switch could work as we thought.
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[[Image:Titech2013_modeling_ninja2.png|500px|thumb|center|Fig. 4-1-13. Switching from LacI to CI]]
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[[Image:Titech2013_modeling_ninja2.png|700px|thumb|center|Fig.2.4.3 Switching from LacI to CI]]
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<em> <h2>Crosstalk circumvention by TetR </h2></em>
<h2>
<h2>
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<p>After the toggle is confirmed, we analyzed the switching performance between Ninja’s cautious state and shuriken state. When switching occurs from cautious state to shuriken state, CI is expressed abundantly by the influence of C12 expressed from E.Samurai. As C12 decomposes, shuriken state should switch back to cautious state.
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<p>After we confirmed the bistability by the toggle switch, we analyzed the switching dynamics.
</p>
</p>
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<p>Fig.2.4.4 shows the g2p expression when it switches from cautious state to shuriken state by the addition of C12. First it stays cautious state, after 300mins, C12 is expressed from E.Samurai. Only when C12 is being produced, g2p expresses. And when C12 decomposes, it will go back to the LacI state.
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<p>From the following analysis, we modified equations (1) and (2) to describe presence of either <i>E. samurai</i> or <i>E. civilian</i>. Each of them accumulates a signaling molecule during its presence.
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</p>
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[[Image:Titech2013_modeling_ninja3.png|700px|thumb|center|Fig.2.4.4 Switching from caution state to shuriken state]]
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<p>Firstly, we considered the situation that when <i>E. ninja</i> switches to the Mimic state. Fig. 4-1-14 shows the switching from the Attack state to the Mimic state which is influenced by 3OC6HSL getting from <i>E. civilian</i>. We can see from this simulation result that when <i>E. civilian</i> comes on the time of 300 min, the Attack state will switch to the Mimic state.
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</p>
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</h2>
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<p>Then, Fig.2.4.5 shows that when E.Samurai comes, civilian state will switch to shuriken state. We can know from the graph that when E.Samurai comes at 300min, civilian state will switch to shuriken state which expresses g2p.
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[[Image:Titech2013_modeling_ninja7.png|500px|thumb|center|Fig. 4-1-14. <i>E. civilian</i> coming (With TetR)]]
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[[Image:Titech2013_modeling_ninja4.png|700px|thumb|center|Fig.2.4.5 Switching from civilian state to shuriken state]]
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<h2>
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<p>When LacI state switches to shuriken state, CI will converge with vibration. This is because not only the toggle switch, but also there are TetR, LacI and CI434 which suppress with each other and vibrates in the circuit. As adding C12 from outside, TetR vibrates and decays, according to the effect, CI will vibrate and be settled down to a constant value. Moreover, the amount of CI decides the expression level of g2p, so we can know g2p will vibrate, too. The following graph shows the vibration and attenuation of TetR.
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<p>During the switching from the Attack state to the Mimic state, the absence of TetR allows activation of <i>lux/tet</i> hybrid promoter. Repression of TetR production by CI434 is indeed important in the circuit. During the Mimic state, TetR accumulates to plateau level. This presence of TetR is important to circumvent crosstalk, which is shown in the next figure (Fig. 4-1-15).
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</p>
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<p>Secondly, we considered the situation that when <i>E. ninja</i> switches to the Attack state. When switching occurs from the Mimic state to the Attack state, CI starts its expression (Fig. 4-1-16). Note that LacI expression from the <i>lux/tet</i> hybrid promoter is prohibited, due to the presence of TetR, even in the presence of 3OC12HSL-LasR complex which can bind to the hybrid promoter for its activation. Abundant presence of 3OC12HSL expressed from <i>E. samurai</i> causes CI overexpression, which stimulates expression of g2p required for the programmed phage release. Though degradation of TetR during the presence <i>E. samurai</i> causes LacI expression from the hybrid promoter, CI expression from <i>las</i> promoter overcomes the effect of LacI. After 3OC12HSL degradation, the model shows the decrease in CI concentration, which stops throwing
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"shuriken" in our scenario.
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[[Image:Titech2013_modeling_ninja5.png|700px|thumb|center|Fig.2.4.6 Switching from civilian state to shuriken state (with TetR)]]
 
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<p>In the end, we consider the situation that when E.Civilian comes. Fig.2.4.7 shows the switching from cautious state to civilian state which is influenced by C6 came from E.Civilian. We can know from this simulation result that when E.Civilian comes on the time of 300min, CI cautious state will switch to civilian state.
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[[Image:Titech2013_modeling_ninja5.png|500px|thumb|center|Fig. 4-1-15. <i>E. samurai</i> coming (With TetR)]]
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[[Image:Titech2013_modeling_ninja6.png|700px|thumb|center|Fig.2.4.7 E.Civilian comes]]
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<h2>
<h2>
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<p>We discuss the effect of CI434 which is for switching from cautious state to civilian state. When changing happens, if there is no CI434, TetR will affect the promoter C6 directly. So before the switching starts, the promoter LacI will be suppressed. CI434 plays an important role in keeping the time until it switches normally. Fig.2.4.8 includes TetR.
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<p>Interestingly, CI expression oscillates and converges by 3OC12HSL induction (see time point 400-1000) (Fig. 4-1-15, which is a magnified graph of Fig. 4-1-14).  This is because there is not only the toggle switch, but also a repressilator by combination among TetR, LacI and CI434. As adding 3OC12HSL from outside, TetR oscillates and decays. According to the effect, CI also vibrates and settles down to a constant value. Moreover, the amount of CI decides the expression level of g2p, so we can see g2p vibration, too.
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[[Image:Titech2013_modeling_ninja7.png|700px|thumb|center|Fig.2.4.8 Switching from civilian state to shuriken state (with TetR)]]
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<h2>
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[[Image:Titech2013_modeling_ninja3.png|500px|thumb|center|Fig. 4-1-16. Switching from the Mimic state to the Attack state]]
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</h2>
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<h3>3.Analytical method of effectiveness of crosstalk prevention circuit
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<h1>3. Analytical method of effectiveness <br><div align="right"> of crosstalk prevention circuit</div></h1>
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</h3>
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<h3>3-1. Modeling without crosstalk prevention circuit</h3>
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<h3>
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3.1 Model without crosstalk prevention circuit</h3>
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<h2>
<h2>
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<p>Since we already have the simulation result of “Ninja” model, to verify the difference of the original toggle circuit which cannot prevent from the crosstalk of signal and “Ninja” circuit, we have to establish the original model. It was defined as follows.
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<p>Since we already have the simulation result, to verify the difference between "Ninja circuit" and the naive "Signal-dependent state change circuit" which doesn’t circumvent the crosstalk of signal, we established the model for the naive circuit. Equations of naive circuit was defined as follows (Fig. 4-1-17).
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[[Image:Titech2013_modeling_ninjaF9.png|700px|thumb|center|Fig.3.1.1 Equation of original circuit]]
 
<h2>
<h2>
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<p>Value of the parameter used here is the same as the value used in Fig.2.4.1
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[[Image:Titech2013_modeling_ninjaF9.png|500px|thumb|center|Fig. 4-1-17. Equations of naive circuit]]
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</h2>
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<h2>
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<p>The value of the parameters used here was the same as that used in Fig. 4-1-11.
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<h3>
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<h3>3-2. Simulation results</h3>
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3.2 Simulation results</h3>
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<h2>
<h2>
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<p>We compare with two circuits about the characteristics of changing from LacI state to CI state. The reason why we won’t compare them in the opposite way (changing from CI state to LacI state) is that crosstalk won’t occur in both directions. We analyzed the case which the initial state is with enough LacI, then it change to the state with enough CI at 300min by the increase of C12 expressed from E.Samurai. The following graph shows the changing of LacI and CI. The solid line presents the case with crosstalk prevention circuit, and the dotted line stands for the case without crosstalk prevention circuit. When there is certain amount of C12 production, LacI is produced in a certain amount in the toggle without crosstalk prevention circuit, and in contrary, the crosstalk would not be conspicuous. But in “Ninja” circuit which there is crosstalk prevention circuit, LacI would not be produced and switching to the CI state is conspicuous.
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<p>
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</p>
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For the dynamics of changing from the Mimic state to the Attack state, we compared the characteristics of both the circuit. The reason why we won’t compare characteristics for the opposite changing from CI state to LacI state is that crosstalk won’t be occur in this changing. We analyzed the following case; the initial state with enough LacI changes to the state with enough CI, by the increase of 3OC12HSL expression from <i>E. samurai</i> who came at 300 min. Fig. 4-1-18 shows the changing of LacI and CI. The solid line presents the case with crosstalk circumvention circuit, and the dotted line stands for the case without crosstalk circumvention circuit. With 3OC12HSL production, LacI is produced in a certain amount in the naive circuit without crosstalk circumvention. On the contrary, "Ninja circuit" actually circumvents the crosstalk to reduce LacI concentration severely. When <i>E. samurai</i> has gone at 1500 min. the concentration of LacI expressed by "Ninja circuit" was about 25 nM. In contrast, the concentration of LacI expressed by the naive circuit, which cannot circumvent from the crosstalk, is 725 nM. Regarding the convergence to 5 nM LacI, we can conclude that "Ninja circuit" will be converged faster than "Naive circuit".
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<p>When E.samurai has gone at 1500min, the concentration of LacI expressed by “Ninja” circuit is about 25nM. In contrast, the concentration of LacI expressed by the original circuit, which cannot prevent from the crosstalk, is 725nM. Regarding the convergence of LacI, we can conclude that LacI expressed by “Ninja” circuit will be converged faster than the original circuit does.
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</p></h2>
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[[Image:Titech2013_modeling_ninja8.png|700px|thumb|center|Fig.3.2.1 Difference between original circuit and “Ninja” circuit]]
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<h2>
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</div><br>
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[[Image:Titech2013_Ninja_State_Switching_2-1_4-3.jpg|500px|thumb|center|Fig. 4-1-18. Difference between "Naive circuit" and "Ninja circuit"]]
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</div>
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</h2>
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<h1>4. Comparing models of the circuit using ODEs and stochastic simulation </h1>
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<h2>
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<p> We also modeled our Ninja circuit by using stochastic simulation and examined that the circuit really should maintain its bistability on both models.
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</p>
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<p>First we examined the case the Attack state switches to the Mimic state. In initial state we added 2 nM 3OC12HSL by pulse, and after 300 min we added 2 nM 3OC6HSL by pulse. The results are shown in below (Fig. 4-1-19: ODEs, Fig. 4-1-20: stochastic simulation ). Even there is an oscillation in the stochastic simulation model, we can indicate that the circuit switched from the Attack state to the Mimic state and maintained both state after decay of signals in both models.
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</p>
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</h2>
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<gallery widths="350px" heights="170px" style="margin-left:auto; margin-right:auto; text-align: left;">
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Image:C12 C6.png‎|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-19. A model using stochastic simulation of state switching from the Attack state to the Mimic state
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Image:Fig4-1-19.png|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-20. A model using ODEs of state switching from the Attack state to the Mimic state
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<p>Next we examined the case the Mimic state switches to the Attack state. In initial state we added 2 nM 3OC6HSL by pulse, and after 300 min we added 2 nM 3OC12HSL by pulse. The results are shown in below (Fig. 4-1-21: ODEs, Fig. 4-1-22: stochastic simulation ). In both models, we can indicate that the circuit switched from the Mimic state to the Attack state and maintained both state after decay of signals.
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<gallery widths="350px" heights="170px" style="margin-left:auto; margin-right:auto; text-align: left;">
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Image:Fig4-1-21.png‎|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-21. A model using stochastic simulation of state switching from the Mimic state to the Attack state</h2>
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Image:Fig4-1-20.png|<h2 style="font-weight: bold; font-size: 120%;">Fig. 4-1-22. A model using ODEs of state switching from the Mimic state to the Attack state</h2>
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<p>By these modeling results, we can say that the toggle switch shows bistability with more persuasiveness.
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<html><div align="center"><a href="https://2013.igem.org/Team:Tokyo_Tech/Modeling/Crosstalk_Circumvention#top"><img src="https://static.igem.org/mediawiki/2013/f/f0/Titeh2013_backtotop.png" width="200px"></a></div></html>
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Latest revision as of 03:22, 29 October 2013


Crosstalk Circumvention Modeling

Contents

1. Introduction

In order to achieve Signal-dependent state change circuit with crosstalk circumvention, we designed "Ninja circuit" (Fig. 4-1-1).

Fig. 4-1-1. Our designed "Ninja circuit"

We analyzed the dynamic characteristics of the whole circuit through the modeling of "Ninja circuit". In addition, we verified how each parameter in the model formula affects the behavior of the circuit.

To understand the difference between our Ninja crosstalk circumvention system and the original circuit, we compared two gene circuits on equal terms.

2. Analytical method of dynamic characteristics
of the circuit

2-1. Building a mathematical model

On the basis of the Hill equation, we built a mathematical model of the "Ninja circuit". The mathematical model is shown in below. Values for each parameter are discussed on Chapter 2-3.

Fig. 4-1-2. Equations for our modeling

We are going to divide these equations into several groups to explain the mathematical model. The first group describes changes of the signaling molecules (Fig. 4-1-3). At this time, because of constant expression of LasR and LuxR, we considered only degradations of 3OC6HSL and 3OC12HSL. They are added as inputs in a pulse manner in this section.

Fig. 4-1-3. Equations of degradations

Secondly, Fig. 4-1-4 shows differential equation of LacI. Since we used tet promoter (Which is repressed by TetR), the first term shows the suppression of TetR. Although hybrid promoters express LacI as an activation by 3OC6HSL, we had to consider the influence of the crosstalk, which is represented as addition. Because our result from wet experiments shows that the expression level by 3OC12HSL input, which causes crosstalk via LasR activation, is about half of that by 3OC6HSL input, we set a3 value as half of a2 value. About equation (3), not only from the hybrid promoter, LacI is also expressed from one side of the toggle switch. For this expression, we added a Hill equation to show suppression by CI. In the end, we added expression amount of the leak, then minus the decomposition item of LacI.

Fig. 4-1-4. The equation of LacI

As the third, CI was expressed not only from las promoter, but also from one side of the toggle switch. As a result, we added a Hill equation (Fig. 4-1-5) to show the suppression by LacI.

Fig. 4-1-5. The equation of CI

Finally, we derived those following equations (Fig. 4-1-6) based on the circuit as well. Mimic indicates the strength of the Mimic state, and Attack indicates the strength of the Attack state.

Fig. 4-1-6. Equations of CI434, TetR, Mimic, Attack, and g2p

2-2. Descriptions of the parameters

Each parameter is defined as the following table (Fig. 4-1-7).

Fig. 4-1-7. Descriptions of each parameter

2-3. Parameter optimization and simulation

We carried out the simulation of this time by using MatLab. Since the amount of the parameters of the differential equation was very large, we tried to minimize the amount of the evaluation function (Fig. 4-1-8).

Fig. 4-1-8. The evaluation function

At time point 0, we added 3OC12HSL. Then 3OC6HSL was added at 300 min. after induction of the Mimic state in toggle switch. If the absolute value of the difference between the integral value of the strength of Attack and Mimic become smaller, we could get the conclusion that toggle switch had high performance. The parameters we explored were a4, a5, and a6. a4 and a5 are maximum expression amounts of LacI and CI in bistable state. a6 and a7 are expression amounts of CI434 and TetR as for crosstalk circumvention. We determined the transfer function of 3OC6HSL-LuxR complex by least squares method fitting from our assay result of Activation of the crosstalk circumvention system circuit by screening the concentration of 3OC6HSL and aTc, which is shown in below (Fig. 4-1-9).


We used values of GFP fluorescence intensity transition of screening the concentration of 3OC6HSL for the fitting. Since the influence lux/tet hybrid promoter gets from TetR is lower when the concentration of aTc is higher, we used values in the case of aTc = 5 µg/mL. Each values of C6 concentration and GFP fluorescence intensity is shown in Fig. 4-1-10. The value "m", the transfer function of 3OC6HSL-LuxR complex, was determined as 2 by the fitting. We used this value as m2 in our model.

As a result of fitting m2 and exploring the a4, a5, a6, and a7 to minimize the evaluation function (10), we found out that it would be the best selection if we take the parameters as follows (Fig. 4-1-11).

Fig. 4-1-11. Value of each parameter

2-4. Simulation results and parametric evaluation

Bistability by the toggle switch in "Ninja circuit"

We firstly confirmed bistability by toggle switch. In initial state, by pulse addition of 2 nM 3OC12HSL, the CI side got induced and maintained even after decay of 3OC12HSL. After 300 min, with pulse addition of 2 nM 3OC6HSL, the toggle switch starts switching to the Mimic state. In addition, the state was maintained after decay of 3OC12HSL. Thus we could get the conclusion that the Mimic state stays stable after the switching.

Fig. 4-1-12. Switching from CI to LacI

Then, we confirmed the performance of the other side of the toggle switch. First, 2 nM 3OC6HSL was added in a pulse manner, then after 300 min. 3OC12HSL was added in a pulse manner. From following graph (Fig. 4-1-13). in combination with Fig. 4-1-12, we could get the conclusion that the toggle switch shows bistability as we thought.

Fig. 4-1-13. Switching from LacI to CI

Crosstalk circumvention by TetR

After we confirmed the bistability by the toggle switch, we analyzed the switching dynamics.

From the following analysis, we modified equations (1) and (2) to describe presence of either E. samurai or E. civilian. Each of them accumulates a signaling molecule during its presence.

Firstly, we considered the situation that when E. ninja switches to the Mimic state. Fig. 4-1-14 shows the switching from the Attack state to the Mimic state which is influenced by 3OC6HSL getting from E. civilian. We can see from this simulation result that when E. civilian comes on the time of 300 min, the Attack state will switch to the Mimic state.

Fig. 4-1-14. E. civilian coming (With TetR)

During the switching from the Attack state to the Mimic state, the absence of TetR allows activation of lux/tet hybrid promoter. Repression of TetR production by CI434 is indeed important in the circuit. During the Mimic state, TetR accumulates to plateau level. This presence of TetR is important to circumvent crosstalk, which is shown in the next figure (Fig. 4-1-15).

Secondly, we considered the situation that when E. ninja switches to the Attack state. When switching occurs from the Mimic state to the Attack state, CI starts its expression (Fig. 4-1-16). Note that LacI expression from the lux/tet hybrid promoter is prohibited, due to the presence of TetR, even in the presence of 3OC12HSL-LasR complex which can bind to the hybrid promoter for its activation. Abundant presence of 3OC12HSL expressed from E. samurai causes CI overexpression, which stimulates expression of g2p required for the programmed phage release. Though degradation of TetR during the presence E. samurai causes LacI expression from the hybrid promoter, CI expression from las promoter overcomes the effect of LacI. After 3OC12HSL degradation, the model shows the decrease in CI concentration, which stops throwing "shuriken" in our scenario.

Fig. 4-1-15. E. samurai coming (With TetR)

Interestingly, CI expression oscillates and converges by 3OC12HSL induction (see time point 400-1000) (Fig. 4-1-15, which is a magnified graph of Fig. 4-1-14). This is because there is not only the toggle switch, but also a repressilator by combination among TetR, LacI and CI434. As adding 3OC12HSL from outside, TetR oscillates and decays. According to the effect, CI also vibrates and settles down to a constant value. Moreover, the amount of CI decides the expression level of g2p, so we can see g2p vibration, too.

Fig. 4-1-16. Switching from the Mimic state to the Attack state

3. Analytical method of effectiveness
of crosstalk prevention circuit

3-1. Modeling without crosstalk prevention circuit

Since we already have the simulation result, to verify the difference between "Ninja circuit" and the naive "Signal-dependent state change circuit" which doesn’t circumvent the crosstalk of signal, we established the model for the naive circuit. Equations of naive circuit was defined as follows (Fig. 4-1-17).

Fig. 4-1-17. Equations of naive circuit

The value of the parameters used here was the same as that used in Fig. 4-1-11.

3-2. Simulation results

For the dynamics of changing from the Mimic state to the Attack state, we compared the characteristics of both the circuit. The reason why we won’t compare characteristics for the opposite changing from CI state to LacI state is that crosstalk won’t be occur in this changing. We analyzed the following case; the initial state with enough LacI changes to the state with enough CI, by the increase of 3OC12HSL expression from E. samurai who came at 300 min. Fig. 4-1-18 shows the changing of LacI and CI. The solid line presents the case with crosstalk circumvention circuit, and the dotted line stands for the case without crosstalk circumvention circuit. With 3OC12HSL production, LacI is produced in a certain amount in the naive circuit without crosstalk circumvention. On the contrary, "Ninja circuit" actually circumvents the crosstalk to reduce LacI concentration severely. When E. samurai has gone at 1500 min. the concentration of LacI expressed by "Ninja circuit" was about 25 nM. In contrast, the concentration of LacI expressed by the naive circuit, which cannot circumvent from the crosstalk, is 725 nM. Regarding the convergence to 5 nM LacI, we can conclude that "Ninja circuit" will be converged faster than "Naive circuit".

Fig. 4-1-18. Difference between "Naive circuit" and "Ninja circuit"

4. Comparing models of the circuit using ODEs and stochastic simulation

We also modeled our Ninja circuit by using stochastic simulation and examined that the circuit really should maintain its bistability on both models.

First we examined the case the Attack state switches to the Mimic state. In initial state we added 2 nM 3OC12HSL by pulse, and after 300 min we added 2 nM 3OC6HSL by pulse. The results are shown in below (Fig. 4-1-19: ODEs, Fig. 4-1-20: stochastic simulation ). Even there is an oscillation in the stochastic simulation model, we can indicate that the circuit switched from the Attack state to the Mimic state and maintained both state after decay of signals in both models.


Next we examined the case the Mimic state switches to the Attack state. In initial state we added 2 nM 3OC6HSL by pulse, and after 300 min we added 2 nM 3OC12HSL by pulse. The results are shown in below (Fig. 4-1-21: ODEs, Fig. 4-1-22: stochastic simulation ). In both models, we can indicate that the circuit switched from the Mimic state to the Attack state and maintained both state after decay of signals.

By these modeling results, we can say that the toggle switch shows bistability with more persuasiveness.