Team:Northwestern

From 2013.igem.org

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<p id = "project-description-title"> <!-- <font size=1>N</font> <font size=2>N</font> <font size=3>N</font> <font size=4>N</font> <font size=5>N</font> --> NUtralize! </p>  
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<p id = "project-description-title"> <font size=1>N</font> <font size=2>N</font> <font size=3>N</font> <font size=4>N</font> <font size=5>N</font> NUtralize! </p>
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    Poor oral health (tooth decay and infection) can lead to many painful symptoms and complicated treatments.  As mouth bacteria are a primary culprit in tooth decay, as lactic acid secreted by natural bacteria in the human mouth decreases pH, leading to cavity formation. The enamel demineralization threshold is known to be around pH 5.5.  The overall vision is to prevent mouth pH from falling below 5.5 by engineering bacteria to sense pH and respond by increasing alkalinity. Our summer project aimed at creating genetic pH sensing elements that would work in the mouth.   Previous research has found that the genes asr and gadA are highly expressed when  pH drops below 5.5. Our project laid the foundation for a dual-state promoter consisting of two promoters in series with a constitutive promoter on at a (tunable) basal level and a downstream pH inducible promoter. In the process, we have characterized a new pH responsive promoter, asr, as well as the individual gadA and constitutive promoters.  Ongoing work will evaluate how promoters in series affect each other and characterize the dual state phenomenon.  This project lays the groundwork for sensing pH drops and could induce enzymes that catalyze reactions to increase the pH.  
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  <p>  Poor oral health (tooth decay and infection) can lead to many painful symptoms and complicated treatments.  Mouth bacteria are a primary culprit in tooth decay, as lactic acid secreted by natural bacteria in the human mouth decreases pH, leading to cavity formation. The enamel demineralization threshold is known to be around pH 5.5.  The overall vision of our project is to prevent mouth pH from falling below 5.5 by engineering bacteria to sense pH and respond by increasing the alkalinity. To do this, we aimed to create genetic pH sensing elements that would work in the mouth. <p/>
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<p>Our project laid the foundation for a dual-state promoter consisting of two promoters in series: a constitutive promoter active at a (tunable) basal level and an upstream, pH-inducible promoter. Previous research has found that the E. coli genes Asr and GadA are highly expressed when pH drops below 5.5. This research drove us to choose the promoter elements for GadA and Asr as our pH-inducible promoters. </p>
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<p>We have characterized a new pH-responsive promoter (Asr) as well as an iGEM-characterized promoter (GadA) and a constitutive promoter (Lpp).  Ongoing work will evaluate how promoters in series affect each other and further characterize the dual state phenomenon. Here we used E. coli for the ease at which it is genetically manipulated to provide proof of principle. Additionally, we tested these promoters with GFP for an easy visual output. Ultimately the aim is to engineer bacteria native to the oral microbiome to sense and respond to drops in pH. We envision that these bacteria will induce enzymes that catalyze reactions to counteract the decrease in pH, preventing the demineralization of the tooth. </p>
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Revision as of 03:05, 28 September 2013



N N N N N NUtralize!

Poor oral health (tooth decay and infection) can lead to many painful symptoms and complicated treatments. Mouth bacteria are a primary culprit in tooth decay, as lactic acid secreted by natural bacteria in the human mouth decreases pH, leading to cavity formation. The enamel demineralization threshold is known to be around pH 5.5. The overall vision of our project is to prevent mouth pH from falling below 5.5 by engineering bacteria to sense pH and respond by increasing the alkalinity. To do this, we aimed to create genetic pH sensing elements that would work in the mouth.

Our project laid the foundation for a dual-state promoter consisting of two promoters in series: a constitutive promoter active at a (tunable) basal level and an upstream, pH-inducible promoter. Previous research has found that the E. coli genes Asr and GadA are highly expressed when pH drops below 5.5. This research drove us to choose the promoter elements for GadA and Asr as our pH-inducible promoters.

We have characterized a new pH-responsive promoter (Asr) as well as an iGEM-characterized promoter (GadA) and a constitutive promoter (Lpp). Ongoing work will evaluate how promoters in series affect each other and further characterize the dual state phenomenon. Here we used E. coli for the ease at which it is genetically manipulated to provide proof of principle. Additionally, we tested these promoters with GFP for an easy visual output. Ultimately the aim is to engineer bacteria native to the oral microbiome to sense and respond to drops in pH. We envision that these bacteria will induce enzymes that catalyze reactions to counteract the decrease in pH, preventing the demineralization of the tooth.

Summary of Problem

Following meals, the pH within the mouth drops substantially which leads to cavities.

pH

The first step in combating cavities is to create a bacteria that can detect pH.

Dual State Promoter

In order for a quick response from basal level, we designed the dual state promoter.