Team
We are a team of seven highly motivated Bachelor- and Master Students at ETH Zürich pursuing various fields such as Biotechnology, Biomedical Engineering, Neurobiology and Bioinformatics. The iGEM project is carried out at one of the youngest departments of ETHZ located in Basel-Department of Biosystems Science and Engineering - flourishing in interdisciplinary biological research. If you're around Basel, make sure to visit our team's lab to play the bio-game Colisweeper!

From Minesweeper to Colisweeper
Colisweeper is a biological version of the Minesweeper computer game. The minefield is replaced by mine and non-mine colonies on an agar plate. Quorum sensing molecule OHHL communicates between colonies that are designed to express different orthogonal hydrolases depending on the signal processed. By pipetting a colorless multi-substrate mix onto mine or non-mine colonies, color appears and indicates the next logical move for the player. In order to flag a mine, a second single substrate can be pipetted on the mine colony.

Information Processing
The non-mine colonies are designed to distinguish between different concentrations of OHHL and translate this information into expression of different sets of hydrolases. They are equipped with mutated LuxR promoters with different OHHL sensitivities which serve as highpass filters. The promoters were created using site-saturation mutagenesis. Through mutation of the LuxR binding sites we were able to tune the promoters to different OHHL affinities .

Hydrolase Reactions
We use a set of orthogonal hydrolases as our reporter system that react within minutes with the added multi-substrate to produce a visible color. The set of hydrolases such as alkaline phosphatase (phoA), β-galactosidase (lacZ), acetylesterase (aes), β-N-Acetylglucosaminidase (nagZ) and β-glucuronidase (gusA) and their respective substrates react to achieve fast and colorful outputs with each color indicative of the next logical move for the player.

The Model
As our system is based on quorum sensing of OHHL, the diffusion of OHHL in the mine field is a vital part of the system. We study the diffusion in our system in a hexagonal grid format with mine and non-mine colonies using a spatio-temporal model. The information from the model was used to validate and improve our system.

Experiments
Starting with characterization of the OHHL diffusion in agar plates we went on to test different sender- and receiver-cell pairs in the hexagonal grid. Initially we used Green fluorescent Protein (GFP) as a reporter to study the OHHL interaction between mine and non mine colonies. Together with promoter mutagenesis and screening, we also tested and characterized different hydrolase-substrate pairs which are crucial to get the game going!

Human practices
Inspired by our Colisweeper project, we analyzed the relationship between synthetic biology and games. For one thing synthetic biology can be used to play common games in a new way, possibly for educational purposes or as a basis for proof-of-principle experiments for new circuits. More recently synthetic biologists also started to use games as a research tool, an innovative approach to make use of crowd-sourcing and distributed computing. We want to find correlations and discuss possible consequences for Synthetic Biology.