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Team:TU-Munich/Modeling/Kill Switch
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====Governing equations==== | ====Governing equations==== | ||
| - | [[File:TUM13_siRNA_graph.png|thumb|right|400px| | + | [[File:TUM13_siRNA_graph.png|thumb|right|400px| '''Figure 1:''' Streptavidin affinity chromatography for the erythromycin esterase]] |
We determined the governing equations of this model to be the following:[[File:TUM13_siRNA_formula.png|center]] | We determined the governing equations of this model to be the following:[[File:TUM13_siRNA_formula.png|center]] | ||
Revision as of 19:32, 3 October 2013
Kill Switch Modeling
Purpose
The idea of our kill switch is to kill off our moss, as soon as it leaves the filter system. For this purpose two methods were proposed:
- siRNA method: When some trigger is activated, siRNA is expressed inhibiting the expression of a vital gene
- nuclease method: When some trigger is activated, a nuclease is released destroying the DNA of the cell
To decide between these two methods we modelled the vitality V of the cell (a number between 0 and 1, so a perfectly functional cell has V=1, a dead cell V=0) and depending on the tested method the concentration of siRNA R and nuclease N as appropriate. Both concentrations are normalized to the unit interval [0,1].
siRNA Model
Governing equations
with initial conditions V(0) = 1 and R(0) = 0, where at the time t=0 the trigger is activated.
Calculation of stable points and analysis
The steady points V* and R* of this system have to satisfy
we get the following quadratic equation for the steady point of V 
If α = 1, the unique steady point is 
.
These are both negative, so this is a stable point, i.e. an attractor.
Now only one of these is in the sensible range, because
- for α > 1:
- for α < 1:
So there is only one steady point in this range, namely:
By expanding the fraction by 
we can rewrite V* as
So using the results from above, we get: 
Defining 
, the eigenvalues are given by
So 
, which means that this is a stable attractor.
Result of our model
So for the siRNA there always is a stable point for the vitality between (but excluding) 0 and 1, so the moss is not killed-off completely, just impeded in its growth.
Interpretation
This result makes intuitive sense, because as the function of the cell is repressed the cell produces less of the inhibiting siRNA, which leads to a regeneration of the cell. Eventually a steady state at a lower vitality is reached, where the vitality stays constant.
Nuclease Modell
Governing equations
We determined the governing equations of this model to be the following:
with initial conditions V(0) = 1 and N(0) = 0, where at the time t=0 the trigger is activated.
Calculation of stable points and analysis
Any steady state given by V* and N* of this system must to satisfy
The eigenvector corresponding to the zero eigenvalue is File:TUM13 nuc eigenvec. It is obvious from the equations that any disturbance away from the steady state along this vector will decay back to the steady state, so this is a stable attractor.
Results of our model
The nuclease always reduces the vitality of the moss to 0, i.e. kills it off completely.
Interpretation
Again this result is very intuitive, since the moss cannot regenerate from the destruction of its genome.
Conclusions
For a functional kill-switch it is necessary, that the cells are actually killed and not just live on with reduced vitality. So based on our modeling results the siRNA approach is not satisfactory, while the nuclease satisfies the requirement. As a result the team pursued the nuclease approach leading to our final kill-switch.
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