Team:Grenoble-EMSE-LSU/Project/Modelling/Building

From 2013.igem.org

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<p>The construction of our model was not as linear as it is described, other modelswere built, tried then abandonned. The aim is to find an explication as simple as possible to the experiments realised, equations describing the behaviour of our bacterial cells with the least parameters as we can. Thus our equations consider the <a href=#MatTime>maturation of fluorscent proteins</a> and the <a href=#AccDam>ability of the bacteria to repair itself</a>.</p>  
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<p>The construction of our model was not as linear as it is described, quite a few modelswere built, tried then abandonned. The aim was to find an explanation as simple as possible the results of the experiments carried out, equations describing the behaviour of our bacterial cells with as few parameters as possible. Thus our equations consider the <a href=#MatTime>maturation of fluorescent proteins</a> and the <a href=#AccDam>ability of the bacteria to repair themselves</a>.</p>  
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<h3>The equation</h3>
<h3>The equation</h3>
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<p>    Our system is made of bacterial cells and ‘KillerRed’ proteins. Bacteria divide and produce KillerRed proteins, and KillerRed proteins respond to light: they fluoresce, degrade (photobleaching) and produce Radical Oxygen Species or ROS (phototoxicity). These reactions are exhibited by all fluorescent proteins, but <a href="/Team:Grenoble-EMSE-LSU/Project/Biology">the 3D structure of KillerRed</a> makes its degradation quicker and its high concentration allows ROS to reach proteins, DNA and membrane within the bacteria and damage its vital functions. )</p>
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<p>    Our system is made of bacterial cells and ‘KillerRed’ proteins. Bacteria divide and produce KillerRed proteins, and KillerRed proteins respond to light: they fluoresce, degrade (photobleaching) and produce Radical Oxygen Species or ROS (phototoxicity). These reactions are exhibited by all fluorescent proteins, but <a href="/Team:Grenoble-EMSE-LSU/Project/Biology">the 3D structure of KillerRed</a> makes its degradation quicker and its high concentration allows ROS to reach proteins, DNA and membrane within the bacteria and damage its vital functions.</p>
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<p>$\diamond$ $aC$ the production of KillerRed.</p>
<p>$\diamond$ $aC$ the production of KillerRed.</p>
<p>$\diamond$ $bIK$ the amount of KillerRed photobleached.</p>
<p>$\diamond$ $bIK$ the amount of KillerRed photobleached.</p>
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<p>$\diamond$ $kIK\frac{K}{C}$ the amount of KillerRed in the bacteria killed in the last step of time.</p>
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<p>$\diamond$ $kIK\frac{K}{C}$ the amount of KillerRed in the bacteria killed in the final time step.</p>
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$r$, $a$, $k$ and $b$ are constants that we will determinate <a href="https://2013.igem.org/Team:Grenoble-EMSE-LSU/Project/Modelling/Parameters">later</a>.
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<p>    Unfortunately, $C$ and $K$ are not measurable variables. The only thing we can quickly and easily measure are the optical density (OD) bound to the amount of bacteria dead AND alive, and the global fluoresence bound to the amount of KillerRed in the bacteria dead AND alive. To be able to compare our model to experimental results, we need two other variables : </p>
<p>    Unfortunately, $C$ and $K$ are not measurable variables. The only thing we can quickly and easily measure are the optical density (OD) bound to the amount of bacteria dead AND alive, and the global fluoresence bound to the amount of KillerRed in the bacteria dead AND alive. To be able to compare our model to experimental results, we need two other variables : </p>

Revision as of 22:17, 1 October 2013

Grenoble-EMSE-LSU, iGEM


Grenoble-EMSE-LSU, iGEM

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