Team:Braunschweig
From 2014.igem.org
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<h1><i>E. cowli</i> - Fighting climate change at the source </h1> | <h1><i>E. cowli</i> - Fighting climate change at the source </h1> | ||
<p class="mr" style="text-align:justify;">Dairy and beef production are important to our daily lives and consumption needs. However, there are serious climate change issues regarding the continual expansion of these industries. The natural microbiota inside the cow’s rumen releases dangerous amounts of greenhouse gases as they help digest the animal's food. Therefore, finding ways to decrease the production of greenhouse gases of dairy cows and cattle is essential in fighting global warming. </p> | <p class="mr" style="text-align:justify;">Dairy and beef production are important to our daily lives and consumption needs. However, there are serious climate change issues regarding the continual expansion of these industries. The natural microbiota inside the cow’s rumen releases dangerous amounts of greenhouse gases as they help digest the animal's food. Therefore, finding ways to decrease the production of greenhouse gases of dairy cows and cattle is essential in fighting global warming. </p> | ||
- | <h3 align="center">In this year’s iGEM project we fight global warming right at the source - the cow's rumen.</h3><br> | + | <h3 align="center">In this year’s iGEM project, we fight global warming right at the source - the cow's rumen.</h3><br> |
<p class="mr" style="text-align:justify;">Using the powerful tools of synthetic biology we make it possible to reduce the methane levels through a genetically engineered bacteria named <i>E. cowli</i>, using the soluble form of the enzyme complex methane monooxygenase (sMMO) for hydroxylation of methane to methanol. We successfully expressed all the subunits in soluble form and, furthermore, were able to prove the activity of the whole enzyme complex. Moreover, the effectivity, feasibility as well as the safety of this project was evaluated using a mathematical model. <br><br> | <p class="mr" style="text-align:justify;">Using the powerful tools of synthetic biology we make it possible to reduce the methane levels through a genetically engineered bacteria named <i>E. cowli</i>, using the soluble form of the enzyme complex methane monooxygenase (sMMO) for hydroxylation of methane to methanol. We successfully expressed all the subunits in soluble form and, furthermore, were able to prove the activity of the whole enzyme complex. Moreover, the effectivity, feasibility as well as the safety of this project was evaluated using a mathematical model. <br><br> | ||
Besides the laboratory-related topics, we also initialized many more activities to spread the idea of synthetic biology and iGEM. On three occasions we had the chance to present ourselves and our project to the broad public, we taught synthetic biology not only in a lecture but also 1-on-1 in a hands-on internship with a pupil and we also used these events for evaluation of the people's opinions on synthetic biology and consumption of animal products. In many discussions with other teams we took the chance to discuss iGEM-related topics such as ethics, safety and intellectual property.<br> | Besides the laboratory-related topics, we also initialized many more activities to spread the idea of synthetic biology and iGEM. On three occasions we had the chance to present ourselves and our project to the broad public, we taught synthetic biology not only in a lecture but also 1-on-1 in a hands-on internship with a pupil and we also used these events for evaluation of the people's opinions on synthetic biology and consumption of animal products. In many discussions with other teams we took the chance to discuss iGEM-related topics such as ethics, safety and intellectual property.<br> |
Revision as of 16:10, 17 October 2014
E. cowli - Fighting climate change at the source
Dairy and beef production are important to our daily lives and consumption needs. However, there are serious climate change issues regarding the continual expansion of these industries. The natural microbiota inside the cow’s rumen releases dangerous amounts of greenhouse gases as they help digest the animal's food. Therefore, finding ways to decrease the production of greenhouse gases of dairy cows and cattle is essential in fighting global warming.
In this year’s iGEM project, we fight global warming right at the source - the cow's rumen.
Using the powerful tools of synthetic biology we make it possible to reduce the methane levels through a genetically engineered bacteria named E. cowli, using the soluble form of the enzyme complex methane monooxygenase (sMMO) for hydroxylation of methane to methanol. We successfully expressed all the subunits in soluble form and, furthermore, were able to prove the activity of the whole enzyme complex. Moreover, the effectivity, feasibility as well as the safety of this project was evaluated using a mathematical model.
Besides the laboratory-related topics, we also initialized many more activities to spread the idea of synthetic biology and iGEM. On three occasions we had the chance to present ourselves and our project to the broad public, we taught synthetic biology not only in a lecture but also 1-on-1 in a hands-on internship with a pupil and we also used these events for evaluation of the people's opinions on synthetic biology and consumption of animal products. In many discussions with other teams we took the chance to discuss iGEM-related topics such as ethics, safety and intellectual property.
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Project
The iGEM Team Braunschweig presents a novel approach towards the reduction of greenhouse gas emissions: We are going to equip the model organism Escherichia coli with the methane monooxygenase (MMO), an enzyme complex enabling methanotrophs to use the greenhouse gas methane as sole source of carbon and energy, hence creating our methane degrading E. cowli.