Team:Peking

From 2013.igem.org

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             <p id="AbstractContent">Some prokaryotes, including Escherichia coli and Pseudomonas putida naturally produce enzymes capable of detecting toxic aromatic molecules and regulating the transcription of corresponding catabolic genes. However, these naturally existing biosensors are limited in terms of their detection range, expression leakage, and induction ratio. This year our team designed a series of aromatic sensors and combined them with related enzymes from their original catabolic pathways to increase the number of molecules the sensors can detect. In order to semi-quantitatively measure the concentrations of these compounds, we constructed a biological band-pass circuit, enabling our sensors to detect the concentrations of target compounds within a certain range. Our system is a fast and easy way of detecting aromatic pollution, and another step forward in ensuring water safety.</p>
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             <p id="AbstractContent">As aromatic pollution levels rise, and along with it the environmental and health hazards that it presents, finding a better way of detecting these aromatic compounds becomes more and more important. Some prokaryotes, including Escherichia coli and Pseudomonas putida, naturally produce proteins capable of both detecting toxic aromatic molecules and regulating the transcription of corresponding catabolic genes. However, these naturally existing biosensors are limited by their detection range, expression leakage, and induction ratio.  
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Using these proteins, our team designed a series of improved aromatic sensors and combined them with related enzymes from their original catabolic pathways to increase the molecule detection range of these sensors. In order to semi-quantitatively measure the concentrations of target compounds, we constructed a biological band-pass circuit, enabling our sensors to detect the concentrations of target compounds within a certain range. In sum, we have been working on a fast, easy and accurate way to detect toxic aromatic compounds.</p>
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Revision as of 13:47, 8 August 2013

AROMATICS BUSTED

A FAST, EASY AND ACCURATE METHOD TO DETECT TOXIC AROMATIC COMPOUND

As aromatic pollution levels rise, and along with it the environmental and health hazards that it presents, finding a better way of detecting these aromatic compounds becomes more and more important. Some prokaryotes, including Escherichia coli and Pseudomonas putida, naturally produce proteins capable of both detecting toxic aromatic molecules and regulating the transcription of corresponding catabolic genes. However, these naturally existing biosensors are limited by their detection range, expression leakage, and induction ratio. Using these proteins, our team designed a series of improved aromatic sensors and combined them with related enzymes from their original catabolic pathways to increase the molecule detection range of these sensors. In order to semi-quantitatively measure the concentrations of target compounds, we constructed a biological band-pass circuit, enabling our sensors to detect the concentrations of target compounds within a certain range. In sum, we have been working on a fast, easy and accurate way to detect toxic aromatic compounds.