Difference between revisions of "Team:TU Darmstadt/Lab/Reporter"

 
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<h1>REPORTER</h1>
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<h1>REPORTING LOW nnAA LEVELS</h1>
 
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                 <div class="abstract">
 
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<p>ABSTRACT<br/></p>
 
<p>ABSTRACT<br/></p>
<p>Glow before you go - What does this actually mean? The aim of our project is to make biology safer by introducing a suicide system to <i>E. coli</i>. Before the suicide is triggered, a <b>reporter protein</b> is expressed to indicate the release of <i>E. coli</i> or to show a deficiency of the non-natural amino acid in the surrounding medium which is necessary for the bacteria to survive. As a reporter protein, we chose <b>mVenus</b> which is a mutant of eYFP. mVenus is located downstream of a promoter which is repressed by a dimeric protein, the <b><i>Zif23-GCN4</i> repressor</b>. This repressor carries an <i>amber</i> mutation at position 4 (F4OMT). As a result, the non-natural amino acid <b><i>O</i>-methyl-L-tyrosine (OMT)</b> is integrated into the protein sequence as long as there is enough OMT in the medium. With decreasing OMT concentration, the translation of the repressor stops due to the early <i>amber</i> stop codon and the repressor cannot bind to the promoter. This leads to expression of the reporter protein mVenus which can be detected by fluorescence measurements.</p>
+
<p>Glow before you go - What does this actually mean? The aim of our project is to make biology safer by introducing a suicide system to <i>E.&nbsp;coli</i>. Before the suicide is triggered, a <b>reporter protein</b> is expressed to indicate the release of <i>E.&nbsp;coli</i> or to show a deficiency of the non-natural amino acid in the surrounding medium which is necessary for the bacteria to survive. As a reporter protein, we chose <b>mVenus</b> which is a mutant of eYFP. mVenus is located downstream of a promoter which is repressed by a dimeric protein, the <b>Zif23-GCN4 repressor</b>. This repressor carries an <i>amber</i> mutation at position 4 (F4OMT). As a result, the non-natural amino acid <b><i>O</i>-methyl-<span style="font-variant:small-caps">l</span>-tyrosine (OMT)</b> is integrated into the protein sequence as long as there is enough OMT in the medium. With decreasing OMT concentration, the translation of the repressor stops due to the early <i>amber</i> stop codon and the repressor cannot bind to the promoter. This leads to expression of the reporter protein mVenus which can be detected by fluorescence measurements.</p>
 
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<div class="content" id="lab2c">
 
<div class="content" id="lab2c">
    <p><h5> The Reporter System</h5></p>
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    <p><h5>Reporter System</h5></p>
<p>For the detection of a low non-natural amino acid concentration, this case <i>O</i>-methyl-L-tyrosine, we designed a reporter system that includes the reporter protein <b>mVenus</b>. In order to make sure that the expression of mVenus does only start at a low OMT concentration, we use a dimeric repressor. An <i>amber</i> mutation was introduced to the DNA sequence of the repressor. This  <a href="https://2016.igem.org/Team:TU_Darmstadt/Lab/OrthogonalPair"><i>amber</i> mutation</a> leads to OMT being integrated in the dimeric repressor protein. However, the repression of the mVenus promoter can only be executed if there is a sufficient amount of OMT in the medium. If the OMT concentration drops below a threshold, the expression of mVenus is induced. As a result, we can detect a yellow fluorescence signal. <br/>
+
<p>For the detection of a low non-natural amino acid concentration, in this case <i>O</i>-methyl-<span style="font-variant:small-caps">l</span>-tyrosine, we designed a reporter system that includes the reporter protein <b>mVenus</b>. In order to make sure that the expression of mVenus does only start at a low OMT concentration, we use a dimeric repressor in which an <i>amber</i> mutation was introduced to the encoding DNA sequence. This  <a href="https://2016.igem.org/Team:TU_Darmstadt/Lab/OrthogonalPair"><i>amber</i> mutation</a> leads to OMT being integrated in the dimeric repressor protein. However, the repression of the mVenus promoter can only be executed if there is a sufficient concentration of OMT in the medium. If the OMT concentration drops below a threshold, the expression of mVenus is induced. As a result, we can detect a yellow fluorescence signal. We utilize a dimeric repressor because this kind of repressor binds strongly to the respective promotor. Moreover, this dimeric repressor creates a sigmoidal repression curve (x&#8209;axis = concentration of OMT; y&#8209;axis = repressor molecule concentration). If the concentration of OMT drops, we quickly obtain a signal.</p>
We utilize a dimeric repressor because this kind of repressor binds strongly to the respective promotor. Moreover, this dimeric repressor creates a sigmoidal repression curve (x&#8209;axis = concentration of OMT; y&#8209;axis = repressor molecule concentration). If the concentration of OMT drops, we quickly obtain a signal.</p>
+
<p>To make sure that the repression does not take place when the concentration drops below the treshold, an LVA degradation tag is expressed with the dimeric repressor. In addition, to ensure that no permanent fluorescent signal is caused by mVenus, it is fused to a LVA degradation tag as well. In consequence, both proteins shall be short-living after their translation [1]. To fit this system to the expression of colicin E2, we can use different Anderson promoters (<a href="http://parts.igem.org/Part:BBa_J23100">BBa_J23100</a>, <a href="http://parts.igem.org/Part:BBa_J23104">BBa_J23104</a>,  <a href="http://parts.igem.org/Part:BBa_J23107">BBa_J23107</a>, <a href="http://parts.igem.org/Part:BBa_J23113">BBa_J23113</a>, and <a href="http://parts.igem.org/Part:BBa_J23114">BBa_J23114</a>). We aimed to find an expression rate ensuring that mVenus is translated before the DNase degrades mVenus encoding DNA and therefore inhibits the protein biosynthesis of mVenus.</p>
<p>To make sure that the repression does not take place when the concentration drops below the treshold, an LVA degradation tag is expressed with the dimeric repressor. In addition, to ensure that no permanent fluorescent signal is caused by mVenus, it is fused to a LVA degradation tag as well. In consequence, both proteins shall be short-living after their translation [1]. For connecting this system to the expression of colicin E2, we can use different Anderson promoters ( <a href="http://parts.igem.org/Part:BBa_J23100">BBa_J23100</a>, <a href="http://parts.igem.org/Part:BBa_J23104">BBa_J23104</a>,  <a href="http://parts.igem.org/Part:BBa_J23107">BBa_J23107</a>, <a href="http://parts.igem.org/Part:BBa_J23113">BBa_J23113</a>, and <a href="http://parts.igem.org/Part:BBa_J23114">BBa_J23114</a>) for finding a fitting expression rate to ensure that mVenus is translated before the DNase degrades the mVenus encoding DNA, making the genomic information inaccessible for the protein biosynthesis of mVenus.</p>
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     <p><h5> mVenus</h5></p>
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     <p><h5>mVenus</h5></p>
     <p>The fluorescent reporter protein mVenus is a mutant of the green fluorescent protein GFP which is often used for fluorescence assays. Due to mutagenesis (F46L/F64L/M153T/V163A/S175G), the maturation time is decreased compared to GFP. In general, the maturation process can be divided in the folding step and formation of the chromophore. During the maturation process, the chromophore formation is the rate-limiting step. After the folding, a torsional rearrangement effects the formation of the chromophore, triggerd by the close proximity of involved residues. After cyclization of two amino acids has taken place, oxidation is the final step. Molecular oxygen is necessary for the reaction that generates the delocalized &#928; electron system, resulting in the fluorophore being maturated and fluorescent. It is protected by the Beta-barrel protein from interfering influences. All the processes are influenced by the general cell- and cell-cycle processes and can be delayed or accelerated. In vitro, the maturation time of mVenus is in average 40 min.  
+
     <p>The fluorescent reporter protein mVenus is a mutant of the green fluorescent protein GFP which is often used for fluorescence assays. Due to mutagenesis (F46L/F64L/M153T/V163A/S175G), the maturation time is decreased compared to GFP. In general, the maturation process can be divided in the folding step and formation of the chromophore. During the maturation process, the chromophore formation is the rate-limiting step. After the folding, a torsional rearrangement effects the formation of the chromophore, triggered by the close proximity of involved residues. After cyclization of two amino acids has taken place, oxidation is the final step. Molecular oxygen is necessary for the reaction that generates the delocalized &#960;&minus;electron system, resulting in the fluorophore being maturated and fluorescent. It is protected by the surrounding &#946;&minus;barrel from interfering influences. All the processes are influenced by the general cell- and cell-cycle processes and can be delayed or accelerated. In vitro, the maturation time of mVenus is in average 40 minutes.  
Another effect of the mutation F46L is the lowered sensitivity to the pH and chloride ion concentration which is one of the drawbacks of wild&#8209;type GFP[2].  
+
Another effect of the mutation F46L is the lowered sensitivity to the pH and the chloride ion concentration, one of the drawbacks of wild&#8209;type GFP [2].  
 
</p>
 
</p>
     <p>mVenus is expressed with a LVA degradation tag to decrease the protein half&#8209;life. Moreover, the reporter is not regulated by any proteins, cofactors or substrates. The lack of disulfide bonds supports the choice of mVenus in our model microorganism <i>E.&nbsp;coli</i>. Its absorption maximum is at 512&nbsp;nm and its emission maximum at 528&nbsp;nm. The atomic mass is approximately 27 kDa. [3,4]  </p><center>
+
     <p>mVenus is expressed with a LVA degradation tag to decrease the protein half&#8209;life. Moreover, the reporter is not regulated by any proteins, cofactors or substrates. The lack of disulfide bonds supports the choice of mVenus in our model microorganism <i>E.&nbsp;coli</i>. Its absorption maximum is at 512&nbsp;nm and its emission maximum at 528&nbsp;nm. The atomic mass is approximately 27 kDa. [3, 4]  </p>
     <div class="bild" style="width:35%;"><img src="https://static.igem.org/mediawiki/2016/5/5d/T--TU_Darmstadt--mVenus_neu.png" width=100%><b>Figure 1:</b> The figure shows the mVenus reporter protein (without LVA degradation tag). The typical Beta-barrel fold is highlighted in yellow. The fluorophore is hidden inside the barrel structure. PDB ID 1MYW, created with the <a href="https://2016.igem.org/Team:TU_Darmstadt/Model">PyMOL Molecular Graphic System</a>.</div></center>
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<center>
 +
     <div class="bild" style="width:35%;"><img src="https://static.igem.org/mediawiki/2016/5/5d/T--TU_Darmstadt--mVenus_neu.png" width=100%><b>Figure 1:</b> Cyrstal structure of the mVenus reporter protein without the LVA degradation tag. Yellow: &#946;&minus;barrel fold enclosing the fluorophore. Created with the <a href="https://2016.igem.org/Team:TU_Darmstadt/Model">PyMOL Molecular Graphic System</a>. <a href="http://www.rcsb.org/pdb/explore.do?structureId=1MYW">PDB entry</a>, <a href="http://www.jbc.org/content/277/52/50573">Rekas <i>et al.</i> 2002</a> .</div></center>
 
 
 
      
 
      
 
      
 
      
 
      
 
      
     <p><h5>Rational Design of the <i>Amber</i> Mutant of the Dimeric Zif23-GCN4 Repressor</h5></p>
+
     <p><h5>Rational Design of an <i>amber</i> mutant of the Zif23-GCN4 repressor</h5></p>
     <p>The regulation of the reporter protein mVenus is carried out by a dimeric zinc finger protein. It binds cooperatively to DNA (a specific promoter region), connecting with the major groove of the DNA. The dimeric Cys2His2 zinc finger protein is the DNA binding domain and attached to a leucine zipper dimerization domain. Therefore, the targeted gene is controlled by the specific DNA binding. The monomers bind the DNA specifically and dimerization happens upon binding.[5]<br/></p>
+
     <p>The regulation of the reporter protein mVenus is carried out by a dimeric zinc finger protein binding cooperatively to a specific promoter region by interfering with its major groove of the DNA. The dimeric Cys2His2 zinc finger protein is the DNA binding domain and attached to a leucine zipper dimerization domain. Hence, the transcription of the targeted gene is repressed by the specific DNA binding. The monomers bind the DNA specifically and dimerization happens upon binding.[5]<br></p>
     <p>In order to control expression of the repressor on a translational level, an <i>amber</i> stop codon is introduced to the sequence of the repressor. First, the mutation site had to be determined. A position was chosen in which the non-natural amino acid should not interfere with the protein structure. A localization close to the N-terminus was selected as the protein expression will stop early once the non-natural amino acid concentration decreases. Phenylalanine was replaced by <i>O</i>-methyl-L-tyrosine (F4OMT) in order to retain stacking interactions. All nearby side chains as well as the helix (starting from R15) were considered and destabilizing mutations were avoided. Additionally, it is important to choose a residue that is not involved in DNA binding. Otherwise, the repressor may lose its function. The residue of the <i>amber</i> mutation is highlighted in yellow in the picture.</p>
+
     <p>In order to control expression of the repressor on a translational level, an <i>amber</i> stop codon is introduced into the sequence of the repressor. First, the mutation site had to be determined. A position was chosen in which the non-natural amino acid should not interfere with the protein structure. A localization close to the N-terminus was selected to stop protein expression early, if the non-natural amino acid concentration drops below a treshold. Phenylalanine was replaced by <i>O</i>-methyl-<span style="font-variant:small-caps">l</span>-tyrosine (F4OMT) in order to retain stacking interactions. All nearby side chains as well as the helix (starting from R15) were considered and destabilizing mutations were avoided. Additionally, it is important to choose a residue that is not involved in DNA binding. Otherwise, the repressor may lose its function. The residue of the <i>amber</i> mutation is highlighted in figure 2.</p>
 
      
 
      
 
     <center>
 
     <center>
   <div class="bild" style="width:60%;"><img src="https://static.igem.org/mediawiki/2016/a/a0/T--TU_Darmstadt--Reporter.gif.gif" width=100%><b>Figure 2:</b> Overview of the <i>amber</i> mutation site in the repressor protein that binds DNA (shown in black). The phenylalanine residue is mutated to <i>O</i>-methyl-L-tyrosine (F4OMT). The residue is located close to the N-terminus of the repressor protein in order to interrupt protein expression early when the non-natural amino acid concentration decreases. Created with Pymol software, PDB ID <i>1LLM</i></div></center>
+
   <div class="bild" style="width:60%;"><img src="https://static.igem.org/mediawiki/2016/4/42/T--TU_Darmstadt--reporter_neu1.png" width=100%><b>Figure 2:</b> Crystall structure of Zif23-GCN4 repressor protein (blue) bound to DNA (black) with the <i>amber</i> mutation site highlighted (yellow). The residue is located close to the N-terminus of the repressor protein in order to interrupt protein expression early in case of low non-natural amino acid concentration. Created with <a href="https://2016.igem.org/Team:TU_Darmstadt/Model">PyMOL Molecular Graphic System</a>, <a href="http://www.rcsb.org/pdb/explore.do?structureId=1llm">PDB entry</a>, <a href="http://pubs.acs.org/doi/abs/10.1021/bi034830b">Wolfe <i>et al.</i> 2003</a></div></center>
 
</div>
 
</div>
 
<div class="references"><h6>References</h6>
 
<div class="references"><h6>References</h6>

Latest revision as of 22:46, 19 October 2016

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ABSTRACT

Glow before you go - What does this actually mean? The aim of our project is to make biology safer by introducing a suicide system to E. coli. Before the suicide is triggered, a reporter protein is expressed to indicate the release of E. coli or to show a deficiency of the non-natural amino acid in the surrounding medium which is necessary for the bacteria to survive. As a reporter protein, we chose mVenus which is a mutant of eYFP. mVenus is located downstream of a promoter which is repressed by a dimeric protein, the Zif23-GCN4 repressor. This repressor carries an amber mutation at position 4 (F4OMT). As a result, the non-natural amino acid O-methyl-l-tyrosine (OMT) is integrated into the protein sequence as long as there is enough OMT in the medium. With decreasing OMT concentration, the translation of the repressor stops due to the early amber stop codon and the repressor cannot bind to the promoter. This leads to expression of the reporter protein mVenus which can be detected by fluorescence measurements.

Reporter System

For the detection of a low non-natural amino acid concentration, in this case O-methyl-l-tyrosine, we designed a reporter system that includes the reporter protein mVenus. In order to make sure that the expression of mVenus does only start at a low OMT concentration, we use a dimeric repressor in which an amber mutation was introduced to the encoding DNA sequence. This amber mutation leads to OMT being integrated in the dimeric repressor protein. However, the repression of the mVenus promoter can only be executed if there is a sufficient concentration of OMT in the medium. If the OMT concentration drops below a threshold, the expression of mVenus is induced. As a result, we can detect a yellow fluorescence signal. We utilize a dimeric repressor because this kind of repressor binds strongly to the respective promotor. Moreover, this dimeric repressor creates a sigmoidal repression curve (x‑axis = concentration of OMT; y‑axis = repressor molecule concentration). If the concentration of OMT drops, we quickly obtain a signal.

To make sure that the repression does not take place when the concentration drops below the treshold, an LVA degradation tag is expressed with the dimeric repressor. In addition, to ensure that no permanent fluorescent signal is caused by mVenus, it is fused to a LVA degradation tag as well. In consequence, both proteins shall be short-living after their translation [1]. To fit this system to the expression of colicin E2, we can use different Anderson promoters (BBa_J23100, BBa_J23104, BBa_J23107, BBa_J23113, and BBa_J23114). We aimed to find an expression rate ensuring that mVenus is translated before the DNase degrades mVenus encoding DNA and therefore inhibits the protein biosynthesis of mVenus.

mVenus

The fluorescent reporter protein mVenus is a mutant of the green fluorescent protein GFP which is often used for fluorescence assays. Due to mutagenesis (F46L/F64L/M153T/V163A/S175G), the maturation time is decreased compared to GFP. In general, the maturation process can be divided in the folding step and formation of the chromophore. During the maturation process, the chromophore formation is the rate-limiting step. After the folding, a torsional rearrangement effects the formation of the chromophore, triggered by the close proximity of involved residues. After cyclization of two amino acids has taken place, oxidation is the final step. Molecular oxygen is necessary for the reaction that generates the delocalized π−electron system, resulting in the fluorophore being maturated and fluorescent. It is protected by the surrounding β−barrel from interfering influences. All the processes are influenced by the general cell- and cell-cycle processes and can be delayed or accelerated. In vitro, the maturation time of mVenus is in average 40 minutes. Another effect of the mutation F46L is the lowered sensitivity to the pH and the chloride ion concentration, one of the drawbacks of wild‑type GFP [2].

mVenus is expressed with a LVA degradation tag to decrease the protein half‑life. Moreover, the reporter is not regulated by any proteins, cofactors or substrates. The lack of disulfide bonds supports the choice of mVenus in our model microorganism E. coli. Its absorption maximum is at 512 nm and its emission maximum at 528 nm. The atomic mass is approximately 27 kDa. [3, 4]

Figure 1: Cyrstal structure of the mVenus reporter protein without the LVA degradation tag. Yellow: β−barrel fold enclosing the fluorophore. Created with the PyMOL Molecular Graphic System. PDB entry, Rekas et al. 2002 .

Rational Design of an amber mutant of the Zif23-GCN4 repressor

The regulation of the reporter protein mVenus is carried out by a dimeric zinc finger protein binding cooperatively to a specific promoter region by interfering with its major groove of the DNA. The dimeric Cys2His2 zinc finger protein is the DNA binding domain and attached to a leucine zipper dimerization domain. Hence, the transcription of the targeted gene is repressed by the specific DNA binding. The monomers bind the DNA specifically and dimerization happens upon binding.[5]

In order to control expression of the repressor on a translational level, an amber stop codon is introduced into the sequence of the repressor. First, the mutation site had to be determined. A position was chosen in which the non-natural amino acid should not interfere with the protein structure. A localization close to the N-terminus was selected to stop protein expression early, if the non-natural amino acid concentration drops below a treshold. Phenylalanine was replaced by O-methyl-l-tyrosine (F4OMT) in order to retain stacking interactions. All nearby side chains as well as the helix (starting from R15) were considered and destabilizing mutations were avoided. Additionally, it is important to choose a residue that is not involved in DNA binding. Otherwise, the repressor may lose its function. The residue of the amber mutation is highlighted in figure 2.

Figure 2: Crystall structure of Zif23-GCN4 repressor protein (blue) bound to DNA (black) with the amber mutation site highlighted (yellow). The residue is located close to the N-terminus of the repressor protein in order to interrupt protein expression early in case of low non-natural amino acid concentration. Created with PyMOL Molecular Graphic System, PDB entry, Wolfe et al. 2003
References
  • [1] Purcell Oliver, Grierson Claire S, Bernardo Mario, Savery Nigel J, Temperature dependence of ssrA-tag mediated protein degradation, Journal of Biological Engineering, vol. 6, pp.13-15, 2012
  • [2] Agata Rekas, Jean-René Alattia, Takeharu Nagai, Atsushi Miyawaki and Mitsuhiko Ikura, Crystal Structure of Venus, a Yellow Fluorescent Protein with Improved Maturation and Reduced Environmental Sensitivity, J. Biol. Chem., vol 277, pp. 50573-50578, 2002
  • [3] Nagai Takeharu, Ibata Keiji,Park Eun Sun, Kubota Mie, Mikoshiba Katsuhiko, A variant of yellow fluorescent protein with fast and efficient maturation for cell-biological applications, Nature Biotechnology, vol. 20, pp. 1585-1588, 2001
  • [4] Sarkar, Pabak Koushik, Srinagesh V Vogel, Steven S Gryczynski, Ignacy Gryczynski, Zygmunt, Photophysical Properties of Cerulean and Venus Fluorescent Proteins, Journal of Biomedical Optics, vol 14, pp. 1-25, 2009
  • [5] Wolfe, Scot A Grant, Robert A Pabo, Carl O, Structure of a Designed Dimeric Zinc Finger Protein Bound to DNA, Biochemistry, vol. 42, pp. 13401-13409, 2003