Team:INSA Toulouse/contenu/project/modelling
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<center><p class="textecaption"><i>Figure 4 : Photographs at 25h of petri dishes containing each 8 Chromobacterium violaceum colonies from 5 mm to 40 mm.</i></p></center> | <center><p class="textecaption"><i>Figure 4 : Photographs at 25h of petri dishes containing each 8 Chromobacterium violaceum colonies from 5 mm to 40 mm.</i></p></center> |
Revision as of 13:33, 26 September 2013
Modelling
AHL diffusion in LB agar medium
To build a binary full adder our system must be able to communicate if necessary a carry. We chose to use a molecule, 3-oxohexanoyl-homoserine lactone (AHL). The AHL is a messenger in our system.
Different systems can be devised to implement the expression and diffusion of the AHL.
The system of Figure 1 operates as follows:
A petri dish containing colonies, which are equidistant from each other. The lights provide information on addition to perform, and the expression and the diffusion of AHL from one colony to another allows the carry propagation.
This system is quite simple but nevertheless raises a certain number of problems:
- A colony does produce enough AHL to induce diffusion of the message?
- Colonies have to be inoculated all at once or progressively during the calculation?
- What is the ideal distance between the colonies? How to avoid excessive diffusion of the AHL, for example from a colony n to colony n +2 rather than a colony n +1?
Production of AHL
To overcome the problem of the amount of AHL required for rapid diffusion of the messenger, we can well imagine a system in which liquid precultures may be deposited. So we get a higher cell density and a greater production of AHL.
Inoculation of cultures
The gradual inoculation of wells during the addition allows, first, to the AHL to diffuse into the medium, and second, not to fall in cell death.
The ideal distance between well
In order to find the ideal distance between two colonies we have searched a model which allow us to know: how does AHL diffuse into the medium and how many time the diffusion need to pass one colony to another.
One dimension model: To overcome the problem of the amount of AHL required for rapid diffusion of the messenger, we can well imagine a system in which liquid precultures may be deposited. So we get a higher cell density and a greater production of AHL.
Figure 3 shows that the largest amount of AHL is between 2.5 and 20 mm. This information is important but we need to develop a model based on time.
Two dimension model:
We realized many experiences in order to measure how AHL diffuse into agar medium. We used a particular bacteria, Chromobacterium violaceum, which is capable to detect presence of AHl by producing a purple pigment, the violacein.
Figure 4 shows petri dishes containing eight colonies of bacteria placed at 5, 10, 15, 20, 25, 30, 35 and 40 mm from the center of the box. With this experience we can track the diffusion of the AHL. Figure 5 represent the evolution of AHL diffusion versus time.
We can see that the ideal distance between two wells is probably between 15 and 25 mm depending on the amount of AHL produced by the bacteria. Indeed, the AHL diffuses rapidly into the medium during the first 5 hours, then the concentration gradient decreases and the diffusion is slower. However, if the bacteria produce too AHL, the diffusion to colony n+1 will be in the first 5 hours but affect the colony n+2 after 24h. In the ideal case would have bacteria produce about 1 nmol per well of AHL.