Difference between revisions of "Team:UNC-Chapel Hill/Project"

 
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<tr><td  bgColor="#56A0D3"></td> <td colspan="3" width="975px" bgColor="#56A0D3" align="center"> <p style="color:white;font-size:20px">DIABETES MELLITUS </p></td> <td  bgColor="#56A0D3"></td> </tr>
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<tr><td  bgColor="#56A0D3"></td> <td colspan="3" width="975px" bgColor="#56A0D3" align="center"> <p style="color:white;font-size:20px">Tri Color Glucose Sensing System </p></td> <td  bgColor="#56A0D3"></td> </tr>
 
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<h3 style="color:#56A0D3; font-size:30px">Project Introduction</h3>
 
<p>Diabetes mellitus is prevalent throughout the world especially in the United States and Mexico. As a treatable disease, diabetes has fallen in the shadow of more life threatening diseases. Although treatable, diabetes can be life threatening, especially to those who cannot afford treatment options. As a solution, we propose a protein controlled system to sense glucose concentrations and release the needed proteins in response. This project executes the first crucial steps of creating a cost effective and accurate means of glucose sensing via the use of Escherichia coli. </p>
 
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<h3 style="color:#56A0D3; font-size:30px">Results</h3>
 
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<img src="https://static.igem.org/mediawiki/2014/thumb/b/b8/UNC_Chapel_Hill_Old_Well_Masthead.jpg/800px-UNC_Chapel_Hill_Old_Well_Masthead.jpg"  width="100%">
 
  
 
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<a href="#type1" style="text-decoration:none;color:#ffffff">Type One </a> </td>
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<a href="#methods" style="text-decoration:none;color:#ffffff">Methodology </a> </td>
 
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<a href="#type2" style="text-decoration:none;color:#ffffff">Type Two </a> </td>
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<a href="#results" style="text-decoration:none;color:#ffffff">Results</a> </td>
 
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<a href="https://2014.igem.org/Team:UNC-Chapel_Hill/Modeling" style="text-decoration:none;color:#ffffff">Modeling </a> </td>
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<a href="#data" style="text-decoration:none;color:#ffffff">Data</a> </td>
 
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<a href="#references" style="text-decoration:none;color:#ffffff">References </a> </td>
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<a href="#future" style="text-decoration:none;color:#ffffff">Future Work </a> </td>
 
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<p id="abstract" style="color:#56A0D3; font-size:30px"> Abstract</p>
 
<p id="abstract" style="color:#56A0D3; font-size:30px"> Abstract</p>
 
<p>This project introduces a novel glucose sensing system in which glucose-responsive promoters drive the expression of three reporter chromoproteins. We designed four novel glucose-sensitive promoters and tested their ability to drive expression of reporter chromoproteins at various glucose concentrations. In conjunction with existing glucose sensitive promoters from the Parts Registry, we used our novel promoters to design a biological device  that expresses different combinations of the three different chromoproteins in response to glucose in Escherichia coli. As such, this device can detect a larger dynamic range of concentrations of selected molecules (e.g., glucose). Our project aims to provide a cheaper alternative for diabetics than current, more expensive, glucose-monitoring systems. While driven by this initial problem, continuing work has shown that our approach may have its greatest potential as a more general molecular sensing platform, capable of being easily customized for the sensing of a broad range of relevant compounds.</p>
 
<p>This project introduces a novel glucose sensing system in which glucose-responsive promoters drive the expression of three reporter chromoproteins. We designed four novel glucose-sensitive promoters and tested their ability to drive expression of reporter chromoproteins at various glucose concentrations. In conjunction with existing glucose sensitive promoters from the Parts Registry, we used our novel promoters to design a biological device  that expresses different combinations of the three different chromoproteins in response to glucose in Escherichia coli. As such, this device can detect a larger dynamic range of concentrations of selected molecules (e.g., glucose). Our project aims to provide a cheaper alternative for diabetics than current, more expensive, glucose-monitoring systems. While driven by this initial problem, continuing work has shown that our approach may have its greatest potential as a more general molecular sensing platform, capable of being easily customized for the sensing of a broad range of relevant compounds.</p>
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<a href="http://www.diabetes.org/" target="_blank"><img src="https://static.igem.org/mediawiki/2014/thumb/e/ee/UNC_Chapel_Hill_Blue_circle.png/617px-UNC_Chapel_Hill_Blue_circle.png" width="200px" align="right" ></a>
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<p id="type1" style="color:#56A0D3; font-size:30px"> Type One Diabetes</p>
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<p id="methods" style="color:#56A0D3; font-size:30px"> Methodology</p>
<h2 style="color:#56A0D3"> Solution </h2>
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<h2 style="color:#56A0D3"> Overall Experimental Design</h2>
<p>Type 1 diabetes is characterized by the body’s immune system destroying insulin producing cells which leads the body to no longer producing insulin, a hormone that promotes the uptake of glucose by cells. We provide a solution for this problem through the creation of a pseudo beta cell that is able to produce insulin in the presence of high glucose level. </p>
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<p>To construct our plasmid, we had to create the three different promoters and chromoproteins separately. In addition, we designed 4 MLC parts based on literature and had them synthesized as g-Blocks. The 4 MLC's differed in strength of promoter, and placement of promoter vs. binding site. This was to determine if we could alter the sensitivity to glucose of the MLC parts based on these differences. We originally attempted 3A assembly of the inducible, repressible, and MLC promoters with the chromoproteins, but since the promoters were very small in size (<50 bp), we would often lose the promoter during the digestion.  Therefore, we decided to have the promoter and chromoprotein synthesized together as a gBlock. The next step was to insert the gBlock into the backbone, but we were only able to successfully insert three different MLC's plus yellow chromoprotein, and the inducible plus blue chromoprotein.  The parts that we had successfully created were then characterized using UV-vis spectroscopy.  The parts were grown in liquid cultures of varying glucose concentration ranging from 3 mg/dL - 500 mg/dL. Using the Nanodrop and 1 cm pathlength micro-cuvettes, the absorbance was taken at the maximum absorbance wavelength of 504 nm for the yellow chromoprotein (according to 2013 Braunschweig) after 24 hours of cell growth. The machine was blanked with a liquid culture of colorless cells that were grown at the same time. The inducible part did not express any blue color after 24 hours of growth. We suspect this was due to the glucose concentrations being too low. </p> 
  
 
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<p id="type2" style="color:#56A0D3; font-size:30px"> Type Two Diabetes</p>
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<p id="results" style="color:#56A0D3; font-size:30px">Results</p>
<h2 style="color:#56A0D3"> Solution </h2>
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<h2 style="color:#56A0D3"> Results</h2>
<p>Type 2 diabetes is characterized by the body being inefficient in its use of insulin (insulin resistance) which causes the pancreas to decrease insulin production (insulin deficiency). Our potential solution for this is to have pseudo L cells release GLP-1 to promote insulin production. GLP-1 is an incretin. Incretins are a group of gastrointestinal hormones that stimulate a decrease in blood glucose levels. GLP-1 has been shown to promote insulin production and also to decrease glucagon production. Glucagon is a peptide hormone produced by alpha cells of the pancreas that raises the concentration of glucose in the bloodstream.</p>
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<p style = "text-align: center"><img src = "https://static.igem.org/mediawiki/2015/e/e9/Unc-cuvettes1.png" width = "900px"></p>
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<p> Shown here are the different intensities of yellow chromoprotein expression with respect to varying glucose concentrations. The parts were grown in LB media of varying glucose concentration ranging from 3mg/dL to 500 mg/dL. These values of glucose concentration were chosen because they were within the range of blood glucose levels. MLC's were expected to behave as glucose inducible promoters; however, from our results, the data appears to show the expression of the chromoprotein decrease as the concentration of glucose increases. All three MLC's seemed to behave in the same fashion and are all sensitive to glucose levels.</p>
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<p style = "text-align: center"><img src = "https://static.igem.org/mediawiki/2015/e/e1/Unc-cuvettes.png" width = "900px"></p>
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<p id = "data"> This picture shows a clearer image of the decreasing yellow color intensity in MLC 4 as glucose concentration is increased. Since the LB media itself is yellow in color, it is diffucult to distinguish between the chromoprotein and the background color of the culture.  The decrease in expression can be more clearly seen in the absorbance vs. concentration plots below. </p>
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<h2 style="color:#56A0D3">Data</h2>
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<p style = "text-align: center"><img src = "https://static.igem.org/mediawiki/2015/e/e8/Unc-mlc2graph.png"><img src = "https://static.igem.org/mediawiki/2015/9/90/Unc-mlc3graph.png"><img src = "https://static.igem.org/mediawiki/2015/4/4e/Unc-mlc4graph.png"></p>  
  
  
 +
<p id = "future"> Absorbance plots for the three MLC parts attached to the yellow chromoprotein. These plots show that instead of behaving as a glucose inducible promoter, the MLC parts instead act like glucose repressible promoters by decreasing in protein expression. In addition, the accurate range of measurement appeared to stop at 200 mg/dL of glucose.  After that concentration, the absorbances were inconsistant and negative suggesting the rate of cell growth was impacted, or some other mechanism was present.</p>
  
 
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<p id="references" style="color:#56A0D3; font-size:30px"> References</p>
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<p id="references" style="color:#56A0D3; font-size:30px"> Future Work</p>
<h2 style="color:#56A0D3"> Thank You </h2>
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<p>Although we created a glucose repressible promoter instead of an inducible, our theoretical construct would still work, as long the sensitivity to glucose differs between the three promoters. We hope to further test the sensitivity of the MLC part and compare it to other repressible promoters in the registry. In addition, we will continue working on piecing the entire construct together and design parts with restriction sites around the promoters to allow for easy exchange of promoters for other teams to customize this tricolor system to their needs. We are looking forward to meeting all these goals at next years iGEM! </p>
<p>Lorem ipsum ad his scripta blandit partiendo, eum fastidii accumsan euripidis in, eum liber hendrerit an. Qui ut wisi vocibus suscipiantur, quo dicit ridens inciderint id. Quo mundi lobortis reformidans eu, legimus senserit definiebas an eos. Eu sit tincidunt incorrupte definitionem, vis mutat affert percipit cu, eirmod consectetuer signiferumque eu per. In usu latine equidem dolores. Quo no falli viris intellegam, ut fugit veritus placerat per.</p>
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Latest revision as of 03:46, 19 September 2015

Tri Color Glucose Sensing System

Abstract Methodology Results Data Future Work

Abstract

This project introduces a novel glucose sensing system in which glucose-responsive promoters drive the expression of three reporter chromoproteins. We designed four novel glucose-sensitive promoters and tested their ability to drive expression of reporter chromoproteins at various glucose concentrations. In conjunction with existing glucose sensitive promoters from the Parts Registry, we used our novel promoters to design a biological device that expresses different combinations of the three different chromoproteins in response to glucose in Escherichia coli. As such, this device can detect a larger dynamic range of concentrations of selected molecules (e.g., glucose). Our project aims to provide a cheaper alternative for diabetics than current, more expensive, glucose-monitoring systems. While driven by this initial problem, continuing work has shown that our approach may have its greatest potential as a more general molecular sensing platform, capable of being easily customized for the sensing of a broad range of relevant compounds.

Methodology

Overall Experimental Design

To construct our plasmid, we had to create the three different promoters and chromoproteins separately. In addition, we designed 4 MLC parts based on literature and had them synthesized as g-Blocks. The 4 MLC's differed in strength of promoter, and placement of promoter vs. binding site. This was to determine if we could alter the sensitivity to glucose of the MLC parts based on these differences. We originally attempted 3A assembly of the inducible, repressible, and MLC promoters with the chromoproteins, but since the promoters were very small in size (<50 bp), we would often lose the promoter during the digestion. Therefore, we decided to have the promoter and chromoprotein synthesized together as a gBlock. The next step was to insert the gBlock into the backbone, but we were only able to successfully insert three different MLC's plus yellow chromoprotein, and the inducible plus blue chromoprotein. The parts that we had successfully created were then characterized using UV-vis spectroscopy. The parts were grown in liquid cultures of varying glucose concentration ranging from 3 mg/dL - 500 mg/dL. Using the Nanodrop and 1 cm pathlength micro-cuvettes, the absorbance was taken at the maximum absorbance wavelength of 504 nm for the yellow chromoprotein (according to 2013 Braunschweig) after 24 hours of cell growth. The machine was blanked with a liquid culture of colorless cells that were grown at the same time. The inducible part did not express any blue color after 24 hours of growth. We suspect this was due to the glucose concentrations being too low.

Results

Results

Shown here are the different intensities of yellow chromoprotein expression with respect to varying glucose concentrations. The parts were grown in LB media of varying glucose concentration ranging from 3mg/dL to 500 mg/dL. These values of glucose concentration were chosen because they were within the range of blood glucose levels. MLC's were expected to behave as glucose inducible promoters; however, from our results, the data appears to show the expression of the chromoprotein decrease as the concentration of glucose increases. All three MLC's seemed to behave in the same fashion and are all sensitive to glucose levels.

This picture shows a clearer image of the decreasing yellow color intensity in MLC 4 as glucose concentration is increased. Since the LB media itself is yellow in color, it is diffucult to distinguish between the chromoprotein and the background color of the culture. The decrease in expression can be more clearly seen in the absorbance vs. concentration plots below.

Data

Absorbance plots for the three MLC parts attached to the yellow chromoprotein. These plots show that instead of behaving as a glucose inducible promoter, the MLC parts instead act like glucose repressible promoters by decreasing in protein expression. In addition, the accurate range of measurement appeared to stop at 200 mg/dL of glucose. After that concentration, the absorbances were inconsistant and negative suggesting the rate of cell growth was impacted, or some other mechanism was present.

Future Work

Although we created a glucose repressible promoter instead of an inducible, our theoretical construct would still work, as long the sensitivity to glucose differs between the three promoters. We hope to further test the sensitivity of the MLC part and compare it to other repressible promoters in the registry. In addition, we will continue working on piecing the entire construct together and design parts with restriction sites around the promoters to allow for easy exchange of promoters for other teams to customize this tricolor system to their needs. We are looking forward to meeting all these goals at next years iGEM!