Team:Austin Texas/kit

From 2014.igem.org

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<h1>Kit Introduction</h1>
<h1>Kit Introduction</h1>
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In recent years the ability to expand the genetic code has been made possible by re-coding the amber stop codon, UAG, via the use of modified tRNA synthetase/tRNA pairs.  These synthetase/tRNA pairs act together to charge the tRNA with a non-canonical amino acid (ncAA), an amino acid that is not one of the 20 amino acids normally encoded by a codon.  While the library of ncAA synthetase/tRNA pairs continues to grow, the properties of each pairing have yet to be systematically characterized using a standardized methodology.
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In recent years the ability to expand the genetic code has been made possible by re-coding the amber stop codon, UAG, via the use of modified tRNA synthetase/tRNA pairs.  These synthetase/tRNA pairs act together to charge a modified tRNA with a non-canonical amino acid (ncAA), an amino acid that is not one of the 20 amino acids normally encoded by a codon.  While the library of ncAA synthetase/tRNA pairs continues to grow, the properties of each pairing have yet to be systematically characterized using a standardized methodology.
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There are certain desired properties of a synthetase/tRNA pair, such as high fidelity and high efficiency, that must be characterized. Without knowing these properties, it is impossible to know how effectively a synthetase/tRNA pair will work and the resulting products will remain vague unless specifically analyzed with each use. The 2014 University of Texas at Austin iGEM Team has developed a standardized method that allows for efficient qualitative and quantitative in vivo characterization of ncAA tRNA synthetase/tRNA pairs. This Expanded Genetic Code Measurement Kit is portable, easy-to-use, and can be quickly used with any synthetase/tRNA pair.
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There are certain desired properties of a synthetase/tRNA pair, such as high fidelity and high efficiency, that must be characterized. Without knowing these properties, it is impossible to know how effectively a synthetase/tRNA pair will work and the resulting products will remain vague unless specifically analyzed with each use. The 2014 University of Texas at Austin iGEM Team has developed a standardized method that allows for efficient qualitative and quantitative in vivo characterization of ncAA tRNA synthetase/tRNA pairs. This Expanded Genetic Code Measurement Kit is portable, easy-to-use, and can be quickly used with any synthetase/tRNA pair.
<h2>Motivation</h2>
<h2>Motivation</h2>
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[[File:Translation of ncAA 10-16-14.png|300px|thumb|right|<b>Figure 1.</b> The process of charging a ncAA, followed by its incorporation during translation.  To do this successfully, a novel tRNA synthetase must be evolved that specifically recognizes the ncAA.]]
[[File:Translation of ncAA 10-16-14.png|300px|thumb|right|<b>Figure 1.</b> The process of charging a ncAA, followed by its incorporation during translation.  To do this successfully, a novel tRNA synthetase must be evolved that specifically recognizes the ncAA.]]
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In order to recode UAG, a synthetase must be mutated to effectively "charge" a ncAA onto the corresponding tRNA. Various methods of directed evolution are typically used to modify a synthetase such that it can interact with and charge a specific ncAA (Liu et al. 2010). The ncAA synthetases available have ranging levels of reported efficiency and are not well characterized.  Many of the ncAA are not widely used, they are published in short articles lacking full documentation, and our own unpublished experiences of working with a number of ncAAs indicate that not all ncAA synthetases are created equal. Thus, we created a standard kit designed to characterize the properties of any ncAA synthetase/tRNA pair. Our goal is to produce a standardized kit that is cheap, reproducible, easy to use, AND easily portable (i.e. you don't need a lot of advanced equipment).
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In order to recode UAG, a synthetase must be mutated to effectively "charge" a ncAA onto the corresponding tRNA. Various methods of directed evolution are typically used to modify a synthetase such that it can interact with and charge a specific ncAA (Liu et al. 2010). The ncAA synthetases available have different levels of reported efficiency, and they are not always well characterized.  Many of the ncAA systems are not widely (re)used. They are published in single, short articles lacking full documentation, and our own experiences of working with a number of ncAAs indicate that not all ncAA synthetases are created equal. Thus, we created a standard kit designed to characterize the properties of any ncAA synthetase/tRNA pair. '''Our goal is to produce a measurement kit that is cheap, reproducible, easy to use, AND easily portable (i.e. you don't need a lot of advanced equipment).'''
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<h1>Background</h1>
<h1>Background</h1>
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The genetic code is a composition of 64 nucleotide triplets (codons) that code for 20 highly conserved amino acids that are essential to all organisms on Earth. While the genetic code is specific, it is also degenerate, meaning that more than one codon can encode for the incorporation of a specific amino acid.  For example, there are six serine codons and three stop codons (called amber, ochre, and opal).  By recoding one of the redundant codons, the recoded codon can signal for the incorporation of a non-canonical amino acid (ncAA) rather than the codon's original usage. Of the three stop codons, the amber codon is the least abundant and thus, the easiest and most efficient to recode.
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The genetic code is composed of 64 nucleotide triplets (codons) that code for 20 highly conserved amino acids that are essential to all organisms on Earth. While the genetic code is specific, it is also degenerate, meaning that more than one codon can encode for the incorporation of a specific amino acid.  For example, there are six serine codons and three stop codons (called amber, ochre, and opal).  By recoding one of the redundant codons, the recoded codon can signal for the incorporation of a non-canonical amino acid (ncAA) rather than the codon's original usage. Of the three stop codons, the amber codon is the least abundant and thus, the easiest and most efficient to recode.
The Schultz lab was the first to expand the genetic code using a unique synthetase/tRNA pair. This synthetase/tRNA pair originated from <i>M. jannaschii</i> tyrosine RS (Mj-TyrRS) and allowed the cell to incorporate <i>o</i>-methyl-<small>L</small>-tyrosine at the amber codon (Wang et al. 2001). Since then, numerous ncAA synthetase/tRNA pairs have been generated. A total of seven ncAAs were used in addition to tyrosine for our project.  [https://2014.igem.org/Team:Austin_Texas/kit#ncAA_Table The full list of amino acids used in this study can be found here].
The Schultz lab was the first to expand the genetic code using a unique synthetase/tRNA pair. This synthetase/tRNA pair originated from <i>M. jannaschii</i> tyrosine RS (Mj-TyrRS) and allowed the cell to incorporate <i>o</i>-methyl-<small>L</small>-tyrosine at the amber codon (Wang et al. 2001). Since then, numerous ncAA synthetase/tRNA pairs have been generated. A total of seven ncAAs were used in addition to tyrosine for our project.  [https://2014.igem.org/Team:Austin_Texas/kit#ncAA_Table The full list of amino acids used in this study can be found here].
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It is important to note that complications can arise when the genetic code is recoded. In a normal bacterium, release factor RF1 is responsible for terminating translation when the ribosome reaches an amber stop codon. To expand the potential of ncAAs, it is vital to avoid termination at amber codons.  Seeing this need, the Church and Isaacs groups engineered a strain of ''E. coli'' that had all of the amber codons removed from the genome, which allowed them to knock out the RF1 gene (Isaacs et al. 2011). The resulting strain, called "amberless" ''E. coli'', has NO AMBER CODONS.  Thus, to better characterize the synthetase/tRNA pairs, we have employed amberless ''E. coli''.  The advantage of this system is that since there are no amber codons in the genome, we cannot accidentally interfere with any cellular processes.  Additionally, since RF1 is knocked out, there is no competition between RF1 and the novel synthetase/tRNA pair.  These factors allow us to better assess the fidelity and efficiency of ncAA tRNA synthetase/tRNA pairs.
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It is important to note that complications can arise when the genetic code is recoded. In a normal bacterium, release factor RF1 is responsible for terminating translation when the ribosome reaches an amber stop codon. To expand the potential of ncAAs, it is vital to avoid termination at amber codons.  Seeing this need, the Church and Isaacs groups engineered a strain of ''E. coli'' that had all of the amber codons removed from the genome, which allowed them to knock out the RF1 gene (Isaacs et al. 2011). The resulting strain, called "amberless" ''E. coli'', has NO AMBER CODONS.  Thus, to better characterize the synthetase/tRNA pairs, we have employed amberless ''E. coli'' as a chassis organism.  The advantage of this system is that since there are no amber codons in the genome, we cannot accidentally interfere with any cellular processes.  Additionally, since RF1 is knocked out, there is no competition between RF1 and the novel synthetase/tRNA pair.  These factors allow us to better assess the fidelity and efficiency of ncAA tRNA synthetase/tRNA pairs.
<h1>Experimental Design and Method</h1>
<h1>Experimental Design and Method</h1>

Revision as of 02:04, 18 October 2014