Difference between revisions of "Team:East Chapel Hill"

 
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{{East_Chapel_Hill}}
 
{{East_Chapel_Hill}}
 
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<h1><p2>Improving the Efficacy of Riboswitch Based Sensor for Visual Detection of Excess Fluoride in Water</h1></p2>
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<hr /><center><h2>Improving the Efficacy of the Fluoride Riboswitch as a Visual Detector of Fluoride Concentrations in Water</h2></center><hr />
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<p style="padding-bottom:0; padding-right: 10%; padding-left:10%; black; font-size:14px;" class="big"> In many poor countries, excess concentrations of fluoride have entered water sources through erosion of sediment and minerals. These toxic concentrations, which are defined by the World Health Organization to be above 1.0mg/L, may result in an array of health complications. Fluoride has been known to induce cell stress, which in turn impairs the function of ameloblasts who are tasked with forming dental enamel. The resulting disease is dental fluorosis, which manifests in the teeth as porous and yellowed enamel. Other potential consequences of exposure to toxic fluoride levels include skeletal fluorosis, which may result in bone deformities, as well as impaired development.
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<p2> Scientists around the world have recognized fluoride as a markedly beneficial resource for protecting tooth enamel from decay. However, excess fluoride can also have an adverse effect on human health. A significant problem arises when excess amounts of fluoride infiltrate drinking water. High fluoride concentrations can have devastating impacts on dental health, especially those of children, and eventually lead to hypomineralization and dental fluorosis.  
Our project involves the development of an operon that will serve as a visual indicator of excess fluoride. We plan to further develop and improve the operon created by last year’s iGEM team, specifically focusing on the fluoride riboswitch and promoter. We are looking for promoters that have an increased gene expression and riboswitches that have increased affinity to fluoride. This would allow for our operon to detect fluoride at levels even lower than 1.0mg/L, a significant improvement from the previous operon.  
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To address this challenge, we aim to first develop an efficient, user-friendly, and cost-sensitive fluoride biosensor using previously characterized fluoride riboswitches. Last year, we developed an operon whose riboswitch was only activated when bound to fluoride. This fluoride-specific activation allowed for selective transcription of the chloramphenicol acetyltransferase (CAT) gene. Bacteria that can express the CAT gene have a resistance to the chloramphenicol antibiotic, and can survive in the presence of chloramphenicol. Consequently, the presence of fluoride allows for bacterial growth in the presence of chloramphenicol. However, this system was not able to detect concentrations low enough to prove useful in realistic applications. This summer, we focused on testing various promoters and riboswitch sequences to reduce the detection threshold and improve the efficacy of our previous operon.
 
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Latest revision as of 02:27, 18 October 2018

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Improving the Efficacy of Riboswitch Based Sensor for Visual Detection of Excess Fluoride in Water


Scientists around the world have recognized fluoride as a markedly beneficial resource for protecting tooth enamel from decay. However, excess fluoride can also have an adverse effect on human health. A significant problem arises when excess amounts of fluoride infiltrate drinking water. High fluoride concentrations can have devastating impacts on dental health, especially those of children, and eventually lead to hypomineralization and dental fluorosis.

To address this challenge, we aim to first develop an efficient, user-friendly, and cost-sensitive fluoride biosensor using previously characterized fluoride riboswitches. Last year, we developed an operon whose riboswitch was only activated when bound to fluoride. This fluoride-specific activation allowed for selective transcription of the chloramphenicol acetyltransferase (CAT) gene. Bacteria that can express the CAT gene have a resistance to the chloramphenicol antibiotic, and can survive in the presence of chloramphenicol. Consequently, the presence of fluoride allows for bacterial growth in the presence of chloramphenicol. However, this system was not able to detect concentrations low enough to prove useful in realistic applications. This summer, we focused on testing various promoters and riboswitch sequences to reduce the detection threshold and improve the efficacy of our previous operon.