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Team:Austin Texas/kit
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| - | + | <h1>Kit Introduction</h1> | |
In recent years the ability to expand the genetic code has been made possible by re-coding the Amber stop codon UAG. As the library of synthetase/tRNA pairs continue to grow for non-canonical incorporation, the characterization of each remains largely vague. Measuring the efficiency of a synthetase can be time consuming and costly when considering all that is necessary for mass spec. The University of Texas iGEM Team has developed a method that allows for in vivo, qualitative, quantitative, and affordable efficiency characterization of synthetase/tRNA pairs. | In recent years the ability to expand the genetic code has been made possible by re-coding the Amber stop codon UAG. As the library of synthetase/tRNA pairs continue to grow for non-canonical incorporation, the characterization of each remains largely vague. Measuring the efficiency of a synthetase can be time consuming and costly when considering all that is necessary for mass spec. The University of Texas iGEM Team has developed a method that allows for in vivo, qualitative, quantitative, and affordable efficiency characterization of synthetase/tRNA pairs. | ||
| - | + | <h1>Background</h1> | |
The genetic code is a composition of 20 highly conserved amino acids that are essential to all organisms on Earth. While specific, the genetic code is degenerate which conveniently adds flexibility to the code. By re-coding one of the redundancies, a codon can signal for the incorporation of an ncAA rather than the original canonical. The Amber codon is the least abundant stop codon of amber, ochre, and opal and thus perfect for re-coding purposes due to minimization of resulting disruptions in the cell. | The genetic code is a composition of 20 highly conserved amino acids that are essential to all organisms on Earth. While specific, the genetic code is degenerate which conveniently adds flexibility to the code. By re-coding one of the redundancies, a codon can signal for the incorporation of an ncAA rather than the original canonical. The Amber codon is the least abundant stop codon of amber, ochre, and opal and thus perfect for re-coding purposes due to minimization of resulting disruptions in the cell. | ||
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| - | + | <h1>Body=</h1> | |
In order to re-code UAG, a synthetase/tRNA pair much be modified to effectively grab onto an ncAA. Various methods of directed evolution are typically used to modify a synthase such that it can grab onto and charge a non-canonical. The library of ncAA synthetases available have a ranging levels of reported efficiency and are not well known. The 2014 UT iGEM Team has created a test kit designed to characterize the efficiency of the ncAA synthetase/tRNA system. | In order to re-code UAG, a synthetase/tRNA pair much be modified to effectively grab onto an ncAA. Various methods of directed evolution are typically used to modify a synthase such that it can grab onto and charge a non-canonical. The library of ncAA synthetases available have a ranging levels of reported efficiency and are not well known. The 2014 UT iGEM Team has created a test kit designed to characterize the efficiency of the ncAA synthetase/tRNA system. | ||
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| - | + | <h1>ncAA Table</h1> | |
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Revision as of 20:52, 7 October 2014
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