Chiba/Project Design

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Chiba logo.png

Introduction | Project Design ( 1.Affinity Tag | 2.Communication Module | 3.Size Control ) | Making Marimos | Our Goal
Acknowledgements | Team Members | [http://chem.tf.chiba-u.jp/igem/ iGEM Chiba Website] | メンバ連絡簿


Project Design

Concept

Fig. 4 Concept

We aimed to make a spherical gathering of bacteria such like marimo by ordering bacteria go get together and stick to each other.

What our system requires

1.Affinity Tag

Make a His-tagged Flagella. We aimed to stick bacteria by displaying histidines (which bonds each other through metal ions) on the flagellar filament.

Fig. 5 His-tagged flagella as a bactria linker. This image depicts only one tail as flagella (the real bacteria have about ten flagella per cell).

2.Communication Module

Make a Bacterial Communication. We make 2 types of cell(sender&receiver) having different gene circuit. Senders sticking each other in advance send a signal to receivers and receivers grow affinity tags.

Fig. 6 Bacterial Communication.

3.Size Control

Make an AHL localized region for quorum sensing.

Fig. 7 Controlling AHL diffusing area and the size of Bacteria Marimo.

How Our System Works

Fig5. How Our System Works.

  1. Senders whose flagella display the histidine tags stick to each other through metal ions. This becomes the core of Bacteria Marimo. The senders also produce AHL to sign the receiver cells.
  2. Receivers express his/flagella and GFP in high [AHL]; only when they get close to the senders core.
  3. Receivers stick to the senders core and themselves through metal ions.... one after another.
  4. As seen, the cluster grows like a snowball. At the same time, the receivers degrade AHL and thus AHL diffusion space around the mixed cluster limited. By controlling the rate of AHL degradation and so on, one can define the size of such Bacteria Marimo.