Team:Groningen/Notebook

From 2008.igem.org

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The restriction of parts and ligating of the parts, we used the method descibed in the [http://partsregistry.org/Assembly:Standard_assembly <font color=#dd0000>Standard Assembly on the Registry</font color>] site. In case of having a promotor or terminator these bricks stayed in the plasmid and the other part was put behind or in front, respectively.
The restriction of parts and ligating of the parts, we used the method descibed in the [http://partsregistry.org/Assembly:Standard_assembly <font color=#dd0000>Standard Assembly on the Registry</font color>] site. In case of having a promotor or terminator these bricks stayed in the plasmid and the other part was put behind or in front, respectively.
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'''Media'''
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For testing how HSL could diffuse trough the media we used two parts, [http://partsregistry.org/Part:BBa_F1610 <font color=#dd0000>BBa_F1610</font color>] as sender device and [http://partsregistry.org/Part:BBa_T9003 <font color=#dd0000>BBa_T9003</font color>] as receiver device. These we grow in Ty medium, but we observed really high GFP background from part BBa_T9003 even without induction. By using EZ medium the background was reduced. For further measurements we decided to use EZ medium.
=='''The model'''==
=='''The model'''==

Revision as of 08:25, 29 July 2008

Starting up

In March we started with brainstorms once a week. During these metings we decided on a project. We had a lot of different ideas. In May we decided to focus on three of the ideas we had:

  • Using flagellar rotation of Bacteria to make a pump of liquid inside a tube.
  • Making E. coli have a memory of events, like light inputs.
  • Make a cellular automata in E. coli and use it to make games or the game of life.

The first idea was hard to make in the 2 or 3 months we had. Here we needed to have bacteria attach to a surface and also have the same orientation in order to have the movement of liquid in the same direction. This topic would probably take us longer than 3 months, so we decided not to move on with it.

For the memory idea we wanted the E. coli insert a small piece of DNA into a plasmid after it got an input. There is a phage system which put an insert inside a certain code in the DNA. However the problem is that we need bacteria to have all just 1 insert at the same time. Moreover we wanted more than one input behind eachother and the bacteria getting inputs in the same order inside a plasmid. This last is probably really hard to obtain, and not possible in the amount of time we have.

The last idea, making a cellular automata seemed to be our best option, since we really like to make a system inside E. coli and have a nice object to model.

Making the system

The labwork

The parts

In June we started to transform E. coli's with the parts. We used the strain DH5alpha, since these we already present at the university. However, we obtained hardly any colony's. We solved this problem by using Invitrogen's Top10 competent cells and making Top10 cells competent ourselves. Still we didn't have a lot of colony's, but we obtained quite some parts. The last parts we really needed for the system, we requested them at iGEM HQ.

Cloning the parts together

The restriction of parts and ligating of the parts, we used the method descibed in the Standard Assembly on the Registry site. In case of having a promotor or terminator these bricks stayed in the plasmid and the other part was put behind or in front, respectively.

Media For testing how HSL could diffuse trough the media we used two parts, BBa_F1610 as sender device and BBa_T9003 as receiver device. These we grow in Ty medium, but we observed really high GFP background from part BBa_T9003 even without induction. By using EZ medium the background was reduced. For further measurements we decided to use EZ medium.

The model

Ruglog.jpg