Team:Edinburgh/Modeling

From 2012.igem.org

(Difference between revisions)
m
m
 
(10 intermediate revisions not shown)
Line 1: Line 1:
{{:Team:Edinburgh/header}}
{{:Team:Edinburgh/header}}
 +
{{Team:Edinburgh/css/navigation-structure.css}}
 +
{{Team:Edinburgh/css/navigation-style.css}}
 +
<html>
<html>
<style type="text/css">
<style type="text/css">
-
/*structure*/
+
/* wiki edit */
-
#modelling-middle{
+
#page-content{
-
width:975px;
+
background-color:#fff;
-
margin-right:auto;
+
border:1px solid #ccc;
-
margin-left:auto;
+
-
border:none;
+
-
padding:10px;
+
}
}
-
/*style - header edit*/
+
/* header edit */
#modelling-page a{
#modelling-page a{
 +
display:block;
background-color: #f2f2f2;
background-color: #f2f2f2;
border-top-right-radius: 10px;
border-top-right-radius: 10px;
Line 18: Line 19:
}
}
#modelling-page a,
#modelling-page a,
-
#modelling-page a:visited,
+
#modelling-page a:visited{
-
#modelling-page a:hover{
+
color: #000;
color: #000;
}
}
#modelling-page a:hover{
#modelling-page a:hover{
cursor: default;
cursor: default;
 +
color: #000;
}
}
</style>
</style>
</html>
</html>
-
<div id="modelling-middle">
+
 
-
We are going to use both Kappa and MATLAB to model electron transfer from the cell. Descriptions to follow.
+
{{:Team:Edinburgh/Modelling/navigation}}
-
</div><!-- /modelling-middle -->
+
 
 +
<html>
 +
<div id="page-middle">
 +
<div id="page-content">
 +
<div class="text">
 +
<p class="h1">
 +
Kappa Modelling - Introduction
 +
</p>
 +
<p class="normal-text">
 +
Part of EdiGEM's project is to implement the MtrCAB electron transfer system from <i>Shewanella oneidensis</i> in <i>Escherichia coli</>. Refer to <a href="https://2012.igem.org/Team:Edinburgh/Project/Bioelectric-Interface">Bioelectric Interface</a> for more information.
 +
<br /><br />
 +
We attempt to model this system by using the stochastic, agent-based language <a href="http://kappalanguage.org/">Kappa</a> and its implementation KaSim 3.0 which can be downloaded from <span class="plainlinks"><a href="https://github.com/jkrivine/KaSim/downloads">here</a></span>. Our kappa code can be found at <span class="plainlinks"><a href="https://github.com/evgeniya-sotirova/EdiGEM12">EdiGEM’s github repository</a></span> together with a detailed description of all made assumptions and used rates.
 +
<br /><br />
 +
The whole process is divided into sub-processes which we try to model separately at first and combine at the end.
 +
</p>
 +
<p class="h1">
 +
Biosensors
 +
</p>
 +
<p class="normal-text">
 +
Our MATLAB modellers decided to take on the task of modelling the bioelectric interface as a biosensor similar to the one created by the Edinburgh iGEM team in 2006. While the KAPPA modellers were looking at the electron transport going on inside the cell between molecules, the MATLAB modellers wanted to look at how the cell becomes an electric interface and if this can become a useful model.  
 +
</br><br>
 +
As described in the video abstract, an inducer molecule starts the process by interacting with the mtrCAB gene which will then lead to the production of the mtrCAB proteins required to make an ordinary cell into a bioelectric interface. If we are to use the bioelectric interface as an arsenic biosensor, the inducer molecule will be the arsenic molecule being detected and the protein being expressed will be the mtrCAB proteins.
 +
</br>
 +
</p>
 +
</div><!-- /text -->
 +
</div><!-- /page-content -->
 +
</div><!-- /page-middle -->
 +
</html>

Latest revision as of 00:03, 27 September 2012

Kappa Modelling - Introduction

Part of EdiGEM's project is to implement the MtrCAB electron transfer system from Shewanella oneidensis in Escherichia coli. Refer to Bioelectric Interface for more information.

We attempt to model this system by using the stochastic, agent-based language Kappa and its implementation KaSim 3.0 which can be downloaded from here. Our kappa code can be found at EdiGEM’s github repository together with a detailed description of all made assumptions and used rates.

The whole process is divided into sub-processes which we try to model separately at first and combine at the end.

Biosensors

Our MATLAB modellers decided to take on the task of modelling the bioelectric interface as a biosensor similar to the one created by the Edinburgh iGEM team in 2006. While the KAPPA modellers were looking at the electron transport going on inside the cell between molecules, the MATLAB modellers wanted to look at how the cell becomes an electric interface and if this can become a useful model.

As described in the video abstract, an inducer molecule starts the process by interacting with the mtrCAB gene which will then lead to the production of the mtrCAB proteins required to make an ordinary cell into a bioelectric interface. If we are to use the bioelectric interface as an arsenic biosensor, the inducer molecule will be the arsenic molecule being detected and the protein being expressed will be the mtrCAB proteins.