Team:Calgary/Project/OurSensor/Reporter

From 2013.igem.org

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<h1>Reporter</h1>
<h1>Reporter</h1>
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<p>For the purposes of this project it was necessary to select a method in which our system could inform the user of a positive test result; a reporter system. Many choices were considered to be the reporter for our system. We decided upon an enzyme/catalyst reporter as we believed that using a reporter such as green fluorescent protein (GFP) simply would not provide a strong enough of a signal for a portable device. GFP would only provide a constant signal that would not increase in intensity over time. The fluorescent output of GFP would also require the device to have the ability to excite the protein with the appropriate wavelength of light. This would add to both the complexity and cost of the device.</p>
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<p>For this project it was necessary to select a method by which our system could inform the user of a positive test result, that is, we needed a reporter system. After careful consideration, we decided upon an enzyme/catalyst reporter as we believed that using a reporter such as green fluorescent protein (GFP) simply would not provide a strong enough of a signal for a portable device. GFP would provide a constant signal that would not increase in intensity over time. The fluorescent output of GFP would also require the device to have the ability to excite the protein with the appropriate wavelength of light. This would add to both the complexity and cost of the device.</p>
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<p>With this knowledge in mind we knew an enzyme with a colour output would be more suitable and easier to understand out in the field. Many common enzymes were analyzed for this purpose. One example is horseradish peroxidase. This enzyme has high enzymatic activity and is commonly used in many biological applications. One problem with its use however is that it cannot be effectively produced within <i>E. coli</i>. There are other common enzymes that do not have this issue such as alkaline phosphatase. These enzymes however are often multimeric which presents an issue with our in vitro strip system. If the enzymes are not able to assemble correctly with the rest of our proteins the device will be ineffective. Based on this knowledge we decided to move forward with two potential reporter systems; the ampicillin resistance enzyme beta-lactamase and chemically modifying ferritin to become a strong catalyst. Why two different reporters? Characterizing two reporter systems, both of which have their own key advantages, gives us flexibility in our platform technology to meet the different criteria that <i> will </i> exist for different detection systems. In addition, during our characterization, if one reporter does not act as it is meant to, we have the ability to focus on the other reporter for our system. Click the links below to learn more about these two systems:</p>
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<p>We decided that an enzyme with a colour output would be more suitable and easier to implement in the field. Many common enzymes were analyzed for this purpose. One example is horseradish peroxidase. This enzyme has high enzymatic activity and is commonly used in many biological applications. One problem with its use however is that it cannot be effectively produced within <i>E. coli</i>. There are other common enzymes that do not have this issue such as alkaline phosphatase. These enzymes however are often multimeric which presents an issue with our in vitro strip system. If the enzymes are not able to assemble correctly with the rest of our proteins the device will be ineffective. Based on this knowledge we decided to move forward with two potential reporter systems: the ampicillin resistance enzyme beta-lactamase and chemically modifying ferritin to become a strong catalyst. Why two different reporters? Characterizing two reporter systems, both of which have their own key advantages, gives us flexibility in our platform technology to meet the different criteria that <i> will </i> exist for different detection systems. In addition, during our characterization, if one reporter does not act as it is meant to, we have the ability to focus on the other reporter for our system. Click the links below to learn more about these two systems:</p>
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<h2>Beta-Lactamase</h2>
<h2>Beta-Lactamase</h2>
<img src="https://static.igem.org/mediawiki/2013/f/f2/2013UCalgaryButtonBetaLac.png">
<img src="https://static.igem.org/mediawiki/2013/f/f2/2013UCalgaryButtonBetaLac.png">
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<p>A small, monomeric enzyme that normally conveys antibiotic resistance can be a reporter enzyme? Click here to delve more into our research about the uses of this enzyme as a reporter in our system!</p>
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<p>A small, monomeric enzyme that normally confers antibiotic resistance as a reporter enzyme? Click here to delve more into our research about the uses of this enzyme as a reporter in our system!</p>
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Revision as of 19:39, 27 September 2013

Reporter

For this project it was necessary to select a method by which our system could inform the user of a positive test result, that is, we needed a reporter system. After careful consideration, we decided upon an enzyme/catalyst reporter as we believed that using a reporter such as green fluorescent protein (GFP) simply would not provide a strong enough of a signal for a portable device. GFP would provide a constant signal that would not increase in intensity over time. The fluorescent output of GFP would also require the device to have the ability to excite the protein with the appropriate wavelength of light. This would add to both the complexity and cost of the device.

We decided that an enzyme with a colour output would be more suitable and easier to implement in the field. Many common enzymes were analyzed for this purpose. One example is horseradish peroxidase. This enzyme has high enzymatic activity and is commonly used in many biological applications. One problem with its use however is that it cannot be effectively produced within E. coli. There are other common enzymes that do not have this issue such as alkaline phosphatase. These enzymes however are often multimeric which presents an issue with our in vitro strip system. If the enzymes are not able to assemble correctly with the rest of our proteins the device will be ineffective. Based on this knowledge we decided to move forward with two potential reporter systems: the ampicillin resistance enzyme beta-lactamase and chemically modifying ferritin to become a strong catalyst. Why two different reporters? Characterizing two reporter systems, both of which have their own key advantages, gives us flexibility in our platform technology to meet the different criteria that will exist for different detection systems. In addition, during our characterization, if one reporter does not act as it is meant to, we have the ability to focus on the other reporter for our system. Click the links below to learn more about these two systems:

Prussian-Blue Ferritin

Combining the power of chemistry and biology we have successfully converted the iron-storage nanoparticle Ferritin into a robust and stable peroxidase-like catalyst. Click here to learn more!

Beta-Lactamase

A small, monomeric enzyme that normally confers antibiotic resistance as a reporter enzyme? Click here to delve more into our research about the uses of this enzyme as a reporter in our system!

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