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

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For a 800 <span class="math"><em>b</em><em>p</em></span> gene and 50 <span class="math"><em>μ</em><em>L</em></span> of solution we have: <br /><span class="math">$n_{mols} = \frac{m_{dna}}{800*6*10^{23}.10^{-12}} \simeq m_{dna} 2*10^{-15}$</span><br /> and <br /><span class="math">$[So] = \frac{m_{dna} 2*10^{-15}}{50*10^{-6}}  
For a 800 <span class="math"><em>b</em><em>p</em></span> gene and 50 <span class="math"><em>μ</em><em>L</em></span> of solution we have: <br /><span class="math">$n_{mols} = \frac{m_{dna}}{800*6*10^{23}.10^{-12}} \simeq m_{dna} 2*10^{-15}$</span><br /> and <br /><span class="math">$[So] = \frac{m_{dna} 2*10^{-15}}{50*10^{-6}}  
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\simeq m_{dna} 0.4*10^{-10} M = 0.04 m_{dna} nM$</span><br /> This means, for example, that in order to obtain <span class="math">10</span> <span class="math"><em>n</em><em>M</em></span> of concentration <span class="math">250</span> <span class="math"><em>n</em><em>g</em></span> of DNA are needed in a solution of <span class="math">50<em>μ</em><em>L</em></span>.</p>
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\simeq m_{dna} 0.4*10^{-10} M = 0.04 m_{dna} $</span><br /> nM. This means, for example, that in order to obtain <span class="math">10</span> <span class="math"><em>n</em><em>M</em></span> of concentration <span class="math">250</span> <span class="math"><em>n</em><em>g</em></span> of DNA are needed in a solution of <span class="math">50<em>μ</em><em>L</em></span>.</p>
<h1 id="results">Results</h1>
<h1 id="results">Results</h1>
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<p>The variable we are interested in optimizing is the concentration of Plug&Play plasmids with the inserted ORF. This variable is presented as a function of the degradation rate <span class="math"><em>k</em><sub><em>d</em></sub></span> and ORF concentration in figure 3 and 4, for CRE and FLP, respectively. The value of RNA degradation rate is indicated by a red arrow.</p>
<p>The variable we are interested in optimizing is the concentration of Plug&Play plasmids with the inserted ORF. This variable is presented as a function of the degradation rate <span class="math"><em>k</em><sub><em>d</em></sub></span> and ORF concentration in figure 3 and 4, for CRE and FLP, respectively. The value of RNA degradation rate is indicated by a red arrow.</p>
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxkd.jpg | caption=<p>Fig. 3. The plasmid concentration with the inserted ORF as a function of degradation rate and ORF concentration for CRE recombinase. The red arrow indicates the RNA degradation rate <span class="math"><em>k</em><sub><em>d</em><em>R</em><em>N</em><em>A</em></sub> = 0. 0023</span> <span class="math">1 / <em>s</em></span>.</p> | size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxkd.jpg | caption=Fig. 3. The plasmid concentration with the inserted ORF as a function of degradation rate and ORF concentration for CRE recombinase. The red arrow indicates the RNA degradation rate <span class="math"><em>k</em><sub><em>d</em><em>R</em><em>N</em><em>A</em></sub> = 0. 0023</span> <span class="math">1 / <em>s</em></span>. | size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxkd_flp.jpg | caption=Fig. 4. Same as figure \ref{fig:ORFxkd} but for FLP recombinase. | size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxkd_flp.jpg | caption=Fig. 4. Same as figure 3 but for FLP recombinase. | size=600px }}
<p>For CRE recombinase, linear DNA degradation do not play a fundamental role in our system and it can even be disregarded, figure 3. This may occur because the circularization of linear DNA by recombinases is faster than the degradation of it. For FLP, however, linear DNA degradation is an important effect and must be taken in account, figure 4. This occurs because the association of the first and second monomers for CRE is significantly higher than for FLP.</p>
<p>For CRE recombinase, linear DNA degradation do not play a fundamental role in our system and it can even be disregarded, figure 3. This may occur because the circularization of linear DNA by recombinases is faster than the degradation of it. For FLP, however, linear DNA degradation is an important effect and must be taken in account, figure 4. This occurs because the association of the first and second monomers for CRE is significantly higher than for FLP.</p>
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<p>One possible strategy to improve the recombination without increasing this amount of DNA is to reduce the volume of the solution before eletroporation, which increase the ORF concentration in the solution. Values lower than <span class="math">10000</span> <span class="math"><em>n</em><em>g</em></span> of DNA may also be satisfactory since the ORF has a antibiotics resistance gene and once the ORF had been inserted the bacteria tend to keep and replicate the plasmid.</p>
<p>One possible strategy to improve the recombination without increasing this amount of DNA is to reduce the volume of the solution before eletroporation, which increase the ORF concentration in the solution. Values lower than <span class="math">10000</span> <span class="math"><em>n</em><em>g</em></span> of DNA may also be satisfactory since the ORF has a antibiotics resistance gene and once the ORF had been inserted the bacteria tend to keep and replicate the plasmid.</p>
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxc.jpg | caption=<p>Fig. 5. The concentration of plasmids with the ORF inserted as a function of ORF mass in concentration and <span class="math"><em>c</em></span> (the fraction of ORF concentration that enters in the bacteria) for CRE recombinase. We suppose that eletroporation was done in a solution of 50 <span class="math"><em>μ</em><em>L</em></span>.</p>| size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxc.jpg | caption=Fig. 5. The concentration of plasmids with the ORF inserted as a function of ORF mass in concentration and <span class="math"><em>c</em></span> (the fraction of ORF concentration that enters in the bacteria) for CRE recombinase. We suppose that eletroporation was done in a solution of 50 <span class="math"><em>μ</em><em>L</em></span>.| size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxc_flp.jpg | caption=Fig. 6. Same as figure \ref{fig:ORFxc} but for FLP recombinase. | size=600px }}
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{{:Team:USP-UNESP-Brazil/Templates/RImage | image=ORFxc_flp.jpg | caption=Fig. 6. Same as figure 5 but for FLP recombinase. | size=600px }}
<h1 id="discussion">Discussion</h1>
<h1 id="discussion">Discussion</h1>
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<p>[4] Zuwen Zhang and Beat Lutz. <em>Cre recombinase-mediated inversion using lox66 and lox71: method to introduce conditional point mutations into the CREB-binding protein.</em> Nucl. Acids Res. (2002) 30 (17): e90.</p>
<p>[4] Zuwen Zhang and Beat Lutz. <em>Cre recombinase-mediated inversion using lox66 and lox71: method to introduce conditional point mutations into the CREB-binding protein.</em> Nucl. Acids Res. (2002) 30 (17): e90.</p>
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Revision as of 01:51, 26 September 2012