Team:USP-UNESP-Brazil/Plasmid Plug n Play/Modeling

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<p>In order to evaluate the feasibility of our project, we developed a mathematical model based on kinetic equations to simulate our experimental design. We considered important to approach this problem mathematically in order to evaluate some issues. Firstly, we evaluated the effect of linear DNA degradation of the ORF when inserted in bacteria after eletroporation. Secondly, we estimated the amount of ORF that should be amplified by PCR in order to optimize the recombination. We compared the results obtained using two recombination protein: CRE and FLP. Finally, we discuss methodologies to improve our design using the standard biological parts.</p>
<p>In order to evaluate the feasibility of our project, we developed a mathematical model based on kinetic equations to simulate our experimental design. We considered important to approach this problem mathematically in order to evaluate some issues. Firstly, we evaluated the effect of linear DNA degradation of the ORF when inserted in bacteria after eletroporation. Secondly, we estimated the amount of ORF that should be amplified by PCR in order to optimize the recombination. We compared the results obtained using two recombination protein: CRE and FLP. Finally, we discuss methodologies to improve our design using the standard biological parts.</p>
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=Table1_pplay.jpeg | caption=Algum comentário ou legenda da figura | size=200px }}
<h1 id="model">Model</h1>
<h1 id="model">Model</h1>
<p>The model we developed was based on the one proposed by Ringrose et al [1]. The authors introduced a model to describe a excision recombination reaction illustrated in Fig. 1. We used the parameters characterized by the authors in order to simulate our experimental design that consists in the circularization and insertion of the ORF in the plasmid. We also introduced a linear DNA degradation rate in the model in order to be more accurate in simulating <em>in vivo</em> process.</p>
<p>The model we developed was based on the one proposed by Ringrose et al [1]. The authors introduced a model to describe a excision recombination reaction illustrated in Fig. 1. We used the parameters characterized by the authors in order to simulate our experimental design that consists in the circularization and insertion of the ORF in the plasmid. We also introduced a linear DNA degradation rate in the model in order to be more accurate in simulating <em>in vivo</em> process.</p>
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<p>where <span class="math"><em>M</em></span> represents the concentration of recombinase monomers and <span class="math"><em>k</em><sub>1</sub></span> and <span class="math"><em>k</em><sub> − 1</sub></span> represent the association and dissociation rate constant, respectively. As described in the above equation, there is only two possibilities of changing the concentration of the state <span class="math"><em>S</em></span>: it can increase (positive sign) if a molecule in the state <span class="math"><em>S</em><sub><em>a</em></sub></span> loses the monomer or it can decrease (negative sign) if a monomer binds the DNA.</p>
<p>where <span class="math"><em>M</em></span> represents the concentration of recombinase monomers and <span class="math"><em>k</em><sub>1</sub></span> and <span class="math"><em>k</em><sub> − 1</sub></span> represent the association and dissociation rate constant, respectively. As described in the above equation, there is only two possibilities of changing the concentration of the state <span class="math"><em>S</em></span>: it can increase (positive sign) if a molecule in the state <span class="math"><em>S</em><sub><em>a</em></sub></span> loses the monomer or it can decrease (negative sign) if a monomer binds the DNA.</p>
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=Table1_pplay.jpeg | caption=Table 1. Association and dissociation rate constants for FLP and Cre binding to DNA, obtained by [1]. | size=600px }}
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<p>Using gel mobility shift assays it is possible to estimate the affinity of the monomer for their target site, represented by the parameters <span class="math"><em>k</em><sub> − 1</sub></span> and <span class="math"><em>k</em><sub>1</sub></span>, as described by Ringrose et al <span class="citation"></span>. They also estimate, using the same proceeding, the parameters <span class="math"><em>k</em><sub> − 2</sub></span> and <span class="math"><em>k</em><sub>2</sub></span> referring to the association and dissociation rate constant of the monomer for a target site when the neighbor site is already occupied by another monomer. Other parameters (<span class="math"><em>k</em><sub>34</sub></span>, <span class="math"><em>k</em><sub> − 34</sub></span>, <span class="math"><em>k</em><sub>5</sub></span> and <span class="math"><em>k</em><sub> − 5</sub></span>) were determined by the authors comparing the simulated and in vitro recombination data, see Table . The entire recombination reaction is illustrated in the figure .</p>
<p>Using gel mobility shift assays it is possible to estimate the affinity of the monomer for their target site, represented by the parameters <span class="math"><em>k</em><sub> − 1</sub></span> and <span class="math"><em>k</em><sub>1</sub></span>, as described by Ringrose et al <span class="citation"></span>. They also estimate, using the same proceeding, the parameters <span class="math"><em>k</em><sub> − 2</sub></span> and <span class="math"><em>k</em><sub>2</sub></span> referring to the association and dissociation rate constant of the monomer for a target site when the neighbor site is already occupied by another monomer. Other parameters (<span class="math"><em>k</em><sub>34</sub></span>, <span class="math"><em>k</em><sub> − 34</sub></span>, <span class="math"><em>k</em><sub>5</sub></span> and <span class="math"><em>k</em><sub> − 5</sub></span>) were determined by the authors comparing the simulated and in vitro recombination data, see Table . The entire recombination reaction is illustrated in the figure .</p>

Revision as of 21:35, 21 September 2012