Team:Harvard BioDesign/Team

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Natural cellular mechanisms are co-opted by synthetic biologists for use in biological sensors. Typical reporters such as GFP are only detectable inside living cells and used to gather information in the laboratory environment.  
Natural cellular mechanisms are co-opted by synthetic biologists for use in biological sensors. Typical reporters such as GFP are only detectable inside living cells and used to gather information in the laboratory environment.  
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Our system encodes sensing information into the amyloid protein curli within bacterial biofilms. Unlike common reporter proteins, curli fibers are highly resistant to degradation and can survive extreme pH and temperature changes extracellularly. Applying chromoproteins engineered to bind specifically to corresponding curli units, information is easily displayed.  
Our system encodes sensing information into the amyloid protein curli within bacterial biofilms. Unlike common reporter proteins, curli fibers are highly resistant to degradation and can survive extreme pH and temperature changes extracellularly. Applying chromoproteins engineered to bind specifically to corresponding curli units, information is easily displayed.  
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Revision as of 23:44, 17 October 2014


HARVARD iGEM 2014!

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Team Information

Past

Present

Natural cellular mechanisms are co-opted by synthetic biologists for use in biological sensors. Typical reporters such as GFP are only detectable inside living cells and used to gather information in the laboratory environment. Our system encodes sensing information into the amyloid protein curli within bacterial biofilms. Unlike common reporter proteins, curli fibers are highly resistant to degradation and can survive extreme pH and temperature changes extracellularly. Applying chromoproteins engineered to bind specifically to corresponding curli units, information is easily displayed.