Team:SJTU-BioX-Shanghai/Project/Subproject2
From 2011.igem.org
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Stop-Codon SwitchBackgroundThe Rare Codon Modulator can only regulate the amount of target protein. To make our device a strict molecular switch that turns on/off protein biosynthesis, we need to eliminate the background. In recent years, stop codons (codonST) and stop codon suppressor tRNAs (tRNASS) are used to incorporate unnatural amino acids in protein biosynthesis. Peter Schultz and his co-workers have made a lot of contributions in this field. The advantage of codonST and tRNASS is that they can incorporate target amino acids without background noise. We make use of codonST and tRNASS as the controlling element for protein biosynthesis. IntroductionWe design a Stop-Codon Switch to turn on/off protein translation. We can control the translation process by controlling whether the ribosome can get through the stop codon placed in the target protein's mRNA. This process can be achieved by controlling the existence of charged tRNASS that recognizes the stop codon. This process is controlled by two elements: The existence of tRNASS aminoacyl tRNA synthetases (aaRS) that can charge tRNASS Reporter: a stop codon is put immediately after the initial codon ATG in the target protein' s mRNA. Design
Click here to see Modeling. 贴图
A stop codon TAG is put immediately after the start codon ATG in the luciferase gene. 贴图 Action: If the ribosome can get through the stop codon with the help of Rare-Codon Switch, luciferase can be expressed. Otherwise, luciferase cannot be expressed. 贴图 The function of Switch is characterized by the amount of luciferase expressed. The amount of luciferase expressed is reflected by the light emitted when luciferase acts on the appropriate luciferin substrate. The light can be measured by luminometer and the quantity is positively correlated with the amount of luciferase and its activity (learn more...). ResultsWe have used Pbla-Luc-TAG ([http://partsregistry.org/wiki/index.php?title=Part:BBa_K567003 BBa_K567003]) as our Reporter. The amount of luciferase produced is reflected using the bioluminescence emitted during the luciferin reaction. Our results demonstrate that TAG insertion into luciferase blocks luciferase production, which was shown in the control group. In the experimental group, with the help of PT7-TDRS([http://partsregistry.org/wiki/index.php?title=Part:BBa_K567011 BBa_K567011]) and tRNAAsp-TAG([http://partsregistry.org/wiki/index.php?title=Part:BBa_K567013 BBa_K567013]),luciferase was produced and bioluminescence was emitted during the luciferin reaction. These results proved that Stop-Codon Switch can turn on protein expression. Yet further work is needed to optimize the device. ConclusionsWe have successfully constructed the Stop-Codon Switch, including the Modulator and the Reporter. We have tested the device and results proved Stop-Codon Switch as a strict molecular switch without background noise. tRNAAsp-TAG recognizes stop codon TAG and can be charged with Asp by modified AspRS.
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