# Team:Minnesota/Modeling

### From 2009.igem.org

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Create mathematical models of our experimental results. Our computational output will guide future research and is the key to determining what is happening at the molecular level of our logical AND gate. | Create mathematical models of our experimental results. Our computational output will guide future research and is the key to determining what is happening at the molecular level of our logical AND gate. | ||

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+ | <h2>Mathematical Modeling</h2> | ||

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+ | [[Image:designgui.jpeg|300px|left|thumb|The MATLAB GUI displays all the reactions and chemical species in the network and allows the user to manipulate all aspects of the system such as reaction rates in order to better mimic experimental results.]] | ||

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+ | It is important to be able to observe the fidelity of the AND gate <i>in silico</i> as well as <i>in vivo</i>. Using our in-house software suite, SynBioSS, we used networks of sixty or more reactions to model the AND gate with different constructs and mutations. Similar to the experimental procedures, we quantified the fidelity of our AND gate with GFP. We also used a MATLAB Graphical User Interface (GUI) to analyze our experimental data. We used our empirical data from the wet lab to perfect our model. | ||

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+ | <h2>Some Basic Modeling</h2> | ||

+ | [[Image:reactionlist.jpg|400px|right|The reaction list in the MATLAB GUI with reactions 3 and 54 highlighted.]] | ||

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+ | We are working with four different combinations of <i>lac</i> and<i>tet</i> (L and T, respectively) operators in our promoter design project. These constructs are: T--, TT-, TTL and -T-. Here, we will demonstrate a little basic modeling we have done of the TTL construct using SynBioSS MATLAB and a design GUI. | ||

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+ | On the SynBioSS wiki, the TTL model is available for download in a .nc format. Upon opening this with the MATLAB GUI, the list of 65 reactions that constitute the repression and induction of transcription. In this model, there are two <i>tet</i> operators TO1 and TO2 and one <i>lac</i> operator LO1. The reactions included in this list account for the repression and induction of transcription in the absence and presence of aTc and IPTG, respectively. In this simple model, we examined reactions 3 and 54, which involve the <i>tet</i> operators being bound by the repressor. (These reactions are shown in the GUI on the left.) We varied the reactions constants from the original 10<sup>8</sup> as low as 0 and as high as 10<sup>9</sup> to see if the fidelity of the AND gate could depend on the reaction rates for repression. We quantified our results by counting molecules of GFP. This not only gave us a clearer idea of what was happening at the molecular level at this promoter site, but also served as a preparation for matching the experimental results computationally. |

## Revision as of 19:42, 16 July 2009

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## Our Modeling Goals

Create mathematical models of our experimental results. Our computational output will guide future research and is the key to determining what is happening at the molecular level of our logical AND gate.

## Mathematical Modeling

It is important to be able to observe the fidelity of the AND gate *in silico* as well as *in vivo*. Using our in-house software suite, SynBioSS, we used networks of sixty or more reactions to model the AND gate with different constructs and mutations. Similar to the experimental procedures, we quantified the fidelity of our AND gate with GFP. We also used a MATLAB Graphical User Interface (GUI) to analyze our experimental data. We used our empirical data from the wet lab to perfect our model.

## Some Basic Modeling

We are working with four different combinations of *lac* and*tet* (L and T, respectively) operators in our promoter design project. These constructs are: T--, TT-, TTL and -T-. Here, we will demonstrate a little basic modeling we have done of the TTL construct using SynBioSS MATLAB and a design GUI.

On the SynBioSS wiki, the TTL model is available for download in a .nc format. Upon opening this with the MATLAB GUI, the list of 65 reactions that constitute the repression and induction of transcription. In this model, there are two *tet* operators TO1 and TO2 and one *lac* operator LO1. The reactions included in this list account for the repression and induction of transcription in the absence and presence of aTc and IPTG, respectively. In this simple model, we examined reactions 3 and 54, which involve the *tet* operators being bound by the repressor. (These reactions are shown in the GUI on the left.) We varied the reactions constants from the original 10^{8} as low as 0 and as high as 10^{9} to see if the fidelity of the AND gate could depend on the reaction rates for repression. We quantified our results by counting molecules of GFP. This not only gave us a clearer idea of what was happening at the molecular level at this promoter site, but also served as a preparation for matching the experimental results computationally.