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

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<p>An important point In our model we have considered all lox sites as loxP. However, there are mutated loxP and a combination of them can improve the insertion of ORF. The main mutated loxP are lox66 and lox71 We did not introduced the lox66 and lox71 in the model for two main reasons: there are no references about the values of rate constants for altered loxP and we prefer to keep the simplicity and clarity of the model. In order to take these variables in consideration, would be necessary more equations and extra hypothesis.</p>
<p>An important point In our model we have considered all lox sites as loxP. However, there are mutated loxP and a combination of them can improve the insertion of ORF. The main mutated loxP are lox66 and lox71 We did not introduced the lox66 and lox71 in the model for two main reasons: there are no references about the values of rate constants for altered loxP and we prefer to keep the simplicity and clarity of the model. In order to take these variables in consideration, would be necessary more equations and extra hypothesis.</p>
<p>Although we did not consider the mutated loxP, we can make some considerations about it. The insertion reaction is favored over the excision reaction by roughly fivefold using mutated recombination, when using CRE recombinases <span class="citation"></span>. This occur because the double mutated loxP has a very low affinity for the CRE monomers. So, an intuitive conclusion is that the combination we chose may optimize the insertion of the ORF in the plasmid. Nevertheless, this conclusion could be false because the altered loxP demands more time in the circularization step since it has a lower association constant for CRE recombinase. This extra amount of time could be such that the degradation of linear DNA plays a fundamental role in the process. However, as it is illustrated in figure , in the case of CRE recombinases, the degradation of linear DNA is not a fundamental variable and it may not interfere. Because of that, the combination of mutated loxP we have chosen must optimize the amount of ORF inserted in the plasmid.</p>
<p>Although we did not consider the mutated loxP, we can make some considerations about it. The insertion reaction is favored over the excision reaction by roughly fivefold using mutated recombination, when using CRE recombinases <span class="citation"></span>. This occur because the double mutated loxP has a very low affinity for the CRE monomers. So, an intuitive conclusion is that the combination we chose may optimize the insertion of the ORF in the plasmid. Nevertheless, this conclusion could be false because the altered loxP demands more time in the circularization step since it has a lower association constant for CRE recombinase. This extra amount of time could be such that the degradation of linear DNA plays a fundamental role in the process. However, as it is illustrated in figure , in the case of CRE recombinases, the degradation of linear DNA is not a fundamental variable and it may not interfere. Because of that, the combination of mutated loxP we have chosen must optimize the amount of ORF inserted in the plasmid.</p>
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<p>[1] L. Ringrose, V. Lounnas, L. Ehrlich, F. Buchholz, R. Wade and A.F. Stewart <em>Comparative kinetic analysis of FLP and cre recombinases: mathematical models for DNA binding and recombination</em>. Journal of Molecular Biology (1998) 284, 363–384</p>
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<p>[2] http://bionumbers.hms.harvard.edu/</p>
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<p>[3] http://partsregistry.org/</p>
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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>

Revision as of 22:34, 21 September 2012