Template:Team:Bonn:NetworkData

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content.titleLong = "Background";
content.titleLong = "Background";
content.summary= "Introduction to the concept of protein activity regulation";
content.summary= "Introduction to the concept of protein activity regulation";
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content.text= " Regulation of protein activity is an important tool in the fields of basic research and synthetic biology[1.1]. The reason for this is that it offers a way to analyze the function of the examined protein. Furthermore the core intent of synthetic biology is the design and production of biological ‘machines’. This is usually accomplished via the modulation of protein activity[1.2].</br></br>An example for this would be the expression of a kill switch that is triggered by the presence of a certain molecule, resulting in cell death.  This example shows that protein regulation generally consists of two parts: the actual method of regulation, and the way this method is induced. In our example, the method of regulation is a rise in cytosolic protein levels and thus an overall increase of activity via an increased rate of expression. The method of induction is the presence of a certain molecule. This molecule could for example be missing in a controlled environment, so that if the organism is to leave, it automatically dies[1.2].<div class='content-image'><img src=' https://static.igem.org/mediawiki/2013/4/47/Bonn-Backgroun%28overview%29-1.jpg'></br> Image detailing the aforementioned example[1.2]</div> There are several different methods for both, actual protein regulation and the induction of this regulation. Through combination of these ‘bricks’, several methods for regulation of protein activity can be designed, each with its own advantages and disadvantages[1.2]. In order to understand the thought process we undertook in designing our own approach in regulation of protein activity, we are going to first explain these ‘bricks’ and discuss their pros and cons.</br><h3>References</h3><a href=’http://www.ncbi.nlm.nih.gov/pubmed/18272963’> [1.1] Amy B Tyszkiewicz & Tom W Muir: ‘Activation of protein splicing with light in yeast’. ‘Nature Methods’ | Vol.5 No.4 | 303 (April 2008)</a></br><a href=’http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3554958/’>[1.2] Gerd H. G. Moe-Behrens et al., ‘Preparing synthetic biology for the world’, Front Microbiol. 2013; 4: 5.</a>";
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content.text= " <a href='' onclick=node(2)>TEST</a>Regulation of protein activity is an important tool in the fields of basic research and synthetic biology[1.1]. The reason for this is that it offers a way to analyze the function of the examined protein. Furthermore the core intent of synthetic biology is the design and production of biological ‘machines’. This is usually accomplished via the modulation of protein activity[1.2].</br></br>An example for this would be the expression of a kill switch that is triggered by the presence of a certain molecule, resulting in cell death.  This example shows that protein regulation generally consists of two parts: the actual method of regulation, and the way this method is induced. In our example, the method of regulation is a rise in cytosolic protein levels and thus an overall increase of activity via an increased rate of expression. The method of induction is the presence of a certain molecule. This molecule could for example be missing in a controlled environment, so that if the organism is to leave, it automatically dies[1.2].<div class='content-image'><img src=' https://static.igem.org/mediawiki/2013/4/47/Bonn-Backgroun%28overview%29-1.jpg'></br> Image detailing the aforementioned example[1.2]</div> There are several different methods for both, actual protein regulation and the induction of this regulation. Through combination of these ‘bricks’, several methods for regulation of protein activity can be designed, each with its own advantages and disadvantages[1.2]. In order to understand the thought process we undertook in designing our own approach in regulation of protein activity, we are going to first explain these ‘bricks’ and discuss their pros and cons.</br><h3>References</h3><a href=’http://www.ncbi.nlm.nih.gov/pubmed/18272963’> [1.1] Amy B Tyszkiewicz & Tom W Muir: ‘Activation of protein splicing with light in yeast’. ‘Nature Methods’ | Vol.5 No.4 | 303 (April 2008)</a></br><a href=’http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3554958/’>[1.2] Gerd H. G. Moe-Behrens et al., ‘Preparing synthetic biology for the world’, Front Microbiol. 2013; 4: 5.</a>";
content.type="Background";
content.type="Background";
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Revision as of 13:30, 3 October 2013