Team:Groningen

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Our goal is to build a system to sense meat spoilage. When a package of meat is saved after opening, a closed sticker containing ''Bacillus subtilis'' spores is activated by breaking the middle compartment, similar to activating a glow-in-the-dark stick), whereby alanine and water are mixed with the spores to cause germination. When the germinated microbes come in contact with volatiles from rotting meat, a pathway is activated which results to the production of a pigment. When this happens, the consumer knows that he has to throw away the food.  
Our goal is to build a system to sense meat spoilage. When a package of meat is saved after opening, a closed sticker containing ''Bacillus subtilis'' spores is activated by breaking the middle compartment, similar to activating a glow-in-the-dark stick), whereby alanine and water are mixed with the spores to cause germination. When the germinated microbes come in contact with volatiles from rotting meat, a pathway is activated which results to the production of a pigment. When this happens, the consumer knows that he has to throw away the food.  
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We use two strategies to make ''Bacillus subtilis'' react to rotten meat volatiles. The first involves TnrA, a transcription regulator involved in nitrogen metabolism. The picture below summerizes this goal pathway. The other strategy comprises the identification of new promoters reacting to rotten meat volatiles. In both cases, the promoter will be combined to a pigment production pathway. A detailed description of our project plan can be found [[Team:Groningen/Project|here]].
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We use two strategies to make ''Bacillus subtilis'' react to rotten meat volatiles. The first involves TnrA, a transcription regulator involved in nitrogen metabolism. The picture below summerizes this goal pathway. The other strategy comprises the identification of new promoters reacting to rotten meat volatiles. In both cases, the promoter will be combined to a pigment production pathway. A detailed description of our project plan can be found [[Team:Groningen/Project|on the project page]].
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Revision as of 10:46, 30 July 2012





Bacillus salus carnis


Every year, 1,300,000,000 tons of food are thrown away worldwide. This is one third of the global food production. One of the reasons for this is the fact that best before dates are imprecise. A reliable way of monitoring whether food is spoiled or not could save up to 600 euro per household per year.

Our goal is to build a system to sense meat spoilage. When a package of meat is saved after opening, a closed sticker containing Bacillus subtilis spores is activated by breaking the middle compartment, similar to activating a glow-in-the-dark stick), whereby alanine and water are mixed with the spores to cause germination. When the germinated microbes come in contact with volatiles from rotting meat, a pathway is activated which results to the production of a pigment. When this happens, the consumer knows that he has to throw away the food.

We use two strategies to make Bacillus subtilis react to rotten meat volatiles. The first involves TnrA, a transcription regulator involved in nitrogen metabolism. The picture below summerizes this goal pathway. The other strategy comprises the identification of new promoters reacting to rotten meat volatiles. In both cases, the promoter will be combined to a pigment production pathway. A detailed description of our project plan can be found on the project page.


JP 20120504 ReactionPathwayOverview v03.png


Fig. h1. Overview of the functional reaction pathway for B. salus carnis.


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