Difference between revisions of "Team:Cardiff Wales"

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<p  align="left" style="background-color:#ffffff"> <br><br> The Cardiff iGEM team of 2017 aimed to produce a high level of gene expression from four promoter constructs in the <i> Nicotiana benthamiana </i> expression system. These constructs were put together using golden gate ligation. Our promoters respond to several different stimuli, are native to <i> Arabidopsis thaliana</i>, and have been characterized previously. We aimed to both quantify their expression levels using luciferase transcriptional units, and use them to create a thyroid stimulating hormone (and thyroid stimulating immunoglobulin) antagonist that could be used to treat Graves' disease. Consequently, we have added several parts to the phytobrick registry. Our antagonist, called TSHantag, has not been previously used as a therapeutic agent, and could be tested <i> in vitro </i> if purified. More details about the project can be found on our <a href="https://2017.igem.org/Team:Cardiff_Wales/projectdescription">project description page</a>.
 
<p  align="left" style="background-color:#ffffff"> <br><br> The Cardiff iGEM team of 2017 aimed to produce a high level of gene expression from four promoter constructs in the <i> Nicotiana benthamiana </i> expression system. These constructs were put together using golden gate ligation. Our promoters respond to several different stimuli, are native to <i> Arabidopsis thaliana</i>, and have been characterized previously. We aimed to both quantify their expression levels using luciferase transcriptional units, and use them to create a thyroid stimulating hormone (and thyroid stimulating immunoglobulin) antagonist that could be used to treat Graves' disease. Consequently, we have added several parts to the phytobrick registry. Our antagonist, called TSHantag, has not been previously used as a therapeutic agent, and could be tested <i> in vitro </i> if purified. More details about the project can be found on our <a href="https://2017.igem.org/Team:Cardiff_Wales/projectdescription">project description page</a>.
 
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We also developed a <a href="https://2017.igem.org/Team:Cardiff_Wales/modelling">model</a> that is designed to be flexible so that it can be used as a tool for other future iGEM teams or even companies. This was designed so that it can estimate how many plants are needed to create a single dose of any plant-produced therapeutic with a given severity, depending on what plant expression system is used. For our project, we used this to estimate how many plants are required to get a single effective dose of our TSH antagonist. We demonstrated the flexibility by changing one variable extensively, so that it shows different expression vectors and systems. Then, we integrated our <a href="https://2017.igem.org/Team:Cardiff_Wales/our_research">research</a> section of our <a href="https://2017.igem.org/Team:Cardiff_Wales/human_practices">human practices</a> with the model, and estimated how many plants would be required using each expression platform to give a single effective dose to every sufferer of Graves' disease in the US, assuming a mean severity of the disease.
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We also developed a <a href="https://2017.igem.org/Team:Cardiff_Wales/Modelling">model</a> that is designed to be flexible so that it can be used as a tool for other future iGEM teams or even companies. This was designed so that it can estimate how many plants are needed to create a single dose of any plant-produced therapeutic with a given severity, depending on what plant expression system is used. For our project, we used this to estimate how many plants are required to get a single effective dose of our TSH antagonist. We demonstrated the flexibility by changing one variable extensively, so that it shows different expression vectors and systems. Then, we integrated our <a href="https://2017.igem.org/Team:Cardiff_Wales/Our_research">research</a> section of our <a href="https://2017.igem.org/Team:Cardiff_Wales/Human_Practices">human practices</a> with the model, and estimated how many plants would be required using each expression platform to give a single effective dose to every sufferer of Graves' disease in the US, assuming a mean severity of the disease.
 
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We have expertise using the tobacco expression system and so welcomed collaborations with iGEM teams who wish to test the function of their proteins in plants! <br><br><br> </p>
 
We have expertise using the tobacco expression system and so welcomed collaborations with iGEM teams who wish to test the function of their proteins in plants! <br><br><br> </p>

Revision as of 15:19, 29 October 2017




Benth Biofactory






The Cardiff iGEM team of 2017 aimed to produce a high level of gene expression from four promoter constructs in the Nicotiana benthamiana expression system. These constructs were put together using golden gate ligation. Our promoters respond to several different stimuli, are native to Arabidopsis thaliana, and have been characterized previously. We aimed to both quantify their expression levels using luciferase transcriptional units, and use them to create a thyroid stimulating hormone (and thyroid stimulating immunoglobulin) antagonist that could be used to treat Graves' disease. Consequently, we have added several parts to the phytobrick registry. Our antagonist, called TSHantag, has not been previously used as a therapeutic agent, and could be tested in vitro if purified. More details about the project can be found on our project description page.

We also developed a model that is designed to be flexible so that it can be used as a tool for other future iGEM teams or even companies. This was designed so that it can estimate how many plants are needed to create a single dose of any plant-produced therapeutic with a given severity, depending on what plant expression system is used. For our project, we used this to estimate how many plants are required to get a single effective dose of our TSH antagonist. We demonstrated the flexibility by changing one variable extensively, so that it shows different expression vectors and systems. Then, we integrated our research section of our human practices with the model, and estimated how many plants would be required using each expression platform to give a single effective dose to every sufferer of Graves' disease in the US, assuming a mean severity of the disease.

We have expertise using the tobacco expression system and so welcomed collaborations with iGEM teams who wish to test the function of their proteins in plants!








Project Abstract



Grave’s Disease arises from the overproduction of the thyroid stimulating hormone (TSH). Such overproduction leads to increased thyroxine levels, consequently resulting in hyperthyroidism. Our project will involve the expression of the human thyroid stimulating hormone antagonist (TSHantag) using the Tobacco expression system. As of yet, there have been no examples using the tobacco system for expression of the TSHantag protein. Therefore, we will design and generate unique transcriptional units (TUs) for expression of TSHantag in tobacco. These TUs will be introduced into tobacco using agrobacterium-mediated transformation. We will optimise the amounts of heterologous protein that can be produced in this system before collaborating with researchers at University Hospital of Wales to test the efficacy of the TSHantag in an in vitro system.