Team:HokkaidoU Japan/RBS

From 2013.igem.org

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       <h1 id="common-header-title">Maestro E.coli</h1>
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       <h1 id="common-header-title">Maestro <span class="italic">E. coli</span></h1>
       <h2 id="common-header-subtitle">RBS</h2>
       <h2 id="common-header-subtitle">RBS</h2>
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<p>
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<h1>Overview</h1>
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To make our optimization kit a better one, we made well-selected sets of RBSs.
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    <p>
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For parts controlling gene expression such as promoters or RBSs, it is desired that their prospective functions are explainable.
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      To make RBS selector, we constructed well-selected sets of RBSs.
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We wanted our parts to have, "transparent structure", "reliable function" and "reproducibility".
+
      For parts controlling gene expression such as promoters or RBSs, it is desired that their prospective functions are explainable.
-
Thus, when making our new parts, we decided to change only one region in mRNA.
+
      We wanted our parts to have, "transparent structure", "reliable function" and "reproducibility".
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</p>
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      Thus, when making our new parts, we decided to change only one region in mRNA.
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<p>
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    </p>
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Ribosome binding site (RBS) is located upstream of initiation codon in mRNA. Translation efficiency depends on RBS sequence.
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    <p>
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RBS has Shine-Dalgarno sequence (SD).
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      Ribosome binding site (RBS) is located upstream of initiation codon in mRNA. Translation efficiency depends on RBS sequence.
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SD binds Anti-Shine-Dalgarno sequence (ASD) on ribosomal 30S subunit.
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      RBS has Shine-Dalgarno sequence (SD).
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Then initiation codon binds with fMet-tRNA anticodon and the translation will begin.
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      SD binds Anti-Shine-Dalgarno sequence (ASD) on ribosomal 30S subunit.
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SD-ASD binding strength is important for translation efficiency.
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      Then initiation codon binds with fMet-tRNA anticodon and the translation will begin.
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However, there are results that show RBS binding to 30S subunit even if there is no SD sequence.
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      SD-ASD binding strength is important for translation efficiency.
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</p>
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      However, there are results that show RBS binding to 30S subunit even if there is no SD sequence.
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<p>
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    </p>
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  There is another place that binds with the ribosome in mRNA.
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    <div class="fig fig400">
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  Upstream of the SD sequence, there is an A/U rich sequence.
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      <img src="https://static.igem.org/mediawiki/2013/d/d5/HokkaidoU_RBS_background1_400.png">
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  This A/U rich sequence binds with S1 protein, which is one of proteins that makes 30S ribosome<sup><a href="#cite-1">[1]</a></sup>.
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      <div><span class="bold">fig.1: Ribosome and mRNA. </span> First, S1 protein binds A/U rich sequence. Then, ASD binds SD.</div>
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  The sequence has an important role to make the translation initiation complex.
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    </div>
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  To make it, mRNA first has to bind with 30S ribosome which results to the binding of SD and ASD.
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    <p>
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  Then A/U rich sequence and S1 protein binds together.
+
      There is another place that binds with the ribosome in mRNA.
-
  The loose binding with A/U rich sequence and S1 protein, leads binding with SD and ASD (Fig.1).
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      Upstream of the SD sequence, there is an A/U rich sequence.
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  Thus, this A/U rich sequence is called translational "enhancer"!
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      This A/U rich sequence binds with S1 protein, which is one of proteins that makes 30S ribosome<sup><a href="#cite-1">[1]</a></sup>.
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</p>
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      The sequence has an important role to make the translation initiation complex.
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<div class="fig">
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      To make it, mRNA first has to bind with 30S ribosome which results to the binding of SD and ASD.
-
  <img src="https://static.igem.org/mediawiki/2013/d/d5/HokkaidoU_RBS_background1_400.png">
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      Then A/U rich sequence and S1 protein binds together.
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  <div>Fig.1: Ribosome and mRNA. First, S1 protein binds A/U rich sequence. Then, ASD binds SD.</div>
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      The loose binding with A/U rich sequence and S1 protein, leads binding with SD and ASD (fig.1).
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</div>
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      Thus, this A/U rich sequence is called translational "enhancer"!
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<p>
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    </p>
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  Vimberg<sup><a href="cite-2">[2]</a></sup> constructed RBSs by changing enhancer sequence and SD length (Fig.2).
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    <p>
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  Although SD length was changed, there wasn't big difference in translation efficiency among RBSs' without enhancer (Fig.3).
+
      Vimberg<sup><a href="#cite-2">[2]</a></sup> constructed RBSs by changing enhancer sequence and SD length (fig.2).
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  But big difference appeared in enhancer RBSs when SD length was changed (Fig.4).
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      Although SD length was changed, there wasn't big difference in translation efficiency among RBSs' without enhancer (fig.3).
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  Strong SDs are stimulated and weak SDs are repressed by A/U rich enhancer.
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      But big difference appeared in enhancer RBSs when SD length was changed (fig.4).
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</p>
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      Strong SDs are stimulated and weak SDs are repressed by A/U rich enhancer.
 +
    </p>
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<div class="fig">
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    <div class="fig fig800">
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  <img src="https://static.igem.org/mediawiki/2013/9/92/HokkaidoU_RBS_background2_800.png">
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      <img src="https://static.igem.org/mediawiki/2013/9/92/HokkaidoU_RBS_background2_800.png">
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  <div>Fig.2: Various enhancer and SD. Vimberg combined 3 enhancers and 10 SDs and measured GFP expression.</div>
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      <div><span class="bold">fig.2: Various enhancer and SD.</span> Vimberg combined 3 enhancers and 10 SDs and measured GFP expression.</div>
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</div>
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    </div>
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<div class="fig">
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    <div class="fig fig400 para">
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  <img src="https://static.igem.org/mediawiki/2013/6/6f/HokkaidoU_RBS_background3_800.png">
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      <img src="https://static.igem.org/mediawiki/2013/c/c2/HokkaidoU2013_RBS_Background3.png">
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  <div>Fig.3: GFP expression in No enhancer RBSs.</div>
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      <div><span class="bold">fig.3: GFP expression in No enhancer RBSs.</span></div>
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</div>
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    </div>
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<div class="fig">
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    <div class="fig fig400 para">
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  <img src="https://static.igem.org/mediawiki/2013/a/ad/HokkaidoU_RBS_background4_800.png">
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      <img src="https://static.igem.org/mediawiki/2013/2/2d/HokkaidoU2013_RBS_Background4.png">
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  <div>Fig.4: GFP expression in A/U rich RBSs.</div>
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      <div><span class="bold">fig.4: GFP expression in A/U rich RBSs.</span></div>
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</div>
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    </div>
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<p>
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    <p>
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  We decided to constructed 4 new RBSs based on Vimberg.
+
      We decided to constructed 4 new RBSs based on Vimberg.
-
  These RBSs have A/U rich enhancer.
+
      These RBSs have A/U rich enhancer.
-
  To change the translation efficiencies we varied the length of SD sequence.
+
      To change the translation efficiencies we varied the length of SD sequence.
-
</p>
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    </p>
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<ol class="citation-list">
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    <ol class="citation-list">
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  <li id="cite-1">B. S. Laursen, H. P. Sørensen, et al. Initiation of Protein Synthesis in Bacteria (2005) Microbiol. Mol. Biol. Rev.</li>
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      <li id="cite-1">B. S. Laursen, H. P. Sørensen, <span class="italic">et al.</span> Initiation of Protein Synthesis in Bacteria (2005) Microbiol. Mol. Biol. Rev.</li>
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  <li id="cite-2">V. Vimberg, A. Tats, et al. Translation initiation region sequence preferences in Escherichia coli (2007) BMC Molecular Biology</li>
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      <li id="cite-2">V. Vimberg, A. Tats, <span class="italic">et al.</span> Translation initiation region sequence preferences in <span class="italic">Escherichia coli</span> (2007) BMC Molecular Biology</li>
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</ol>
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    </ol>
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<div id="next-page">
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<a href="https://2013.igem.org/Team:HokkaidoU_Japan/RBS/Methods"><div class="arrow-div"></div><span>Methods</span></a>
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</div>
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Latest revision as of 02:52, 29 October 2013

Maestro E. coli

RBS

Overview

To make RBS selector, we constructed well-selected sets of RBSs. For parts controlling gene expression such as promoters or RBSs, it is desired that their prospective functions are explainable. We wanted our parts to have, "transparent structure", "reliable function" and "reproducibility". Thus, when making our new parts, we decided to change only one region in mRNA.

Ribosome binding site (RBS) is located upstream of initiation codon in mRNA. Translation efficiency depends on RBS sequence. RBS has Shine-Dalgarno sequence (SD). SD binds Anti-Shine-Dalgarno sequence (ASD) on ribosomal 30S subunit. Then initiation codon binds with fMet-tRNA anticodon and the translation will begin. SD-ASD binding strength is important for translation efficiency. However, there are results that show RBS binding to 30S subunit even if there is no SD sequence.

fig.1: Ribosome and mRNA. First, S1 protein binds A/U rich sequence. Then, ASD binds SD.

There is another place that binds with the ribosome in mRNA. Upstream of the SD sequence, there is an A/U rich sequence. This A/U rich sequence binds with S1 protein, which is one of proteins that makes 30S ribosome[1]. The sequence has an important role to make the translation initiation complex. To make it, mRNA first has to bind with 30S ribosome which results to the binding of SD and ASD. Then A/U rich sequence and S1 protein binds together. The loose binding with A/U rich sequence and S1 protein, leads binding with SD and ASD (fig.1). Thus, this A/U rich sequence is called translational "enhancer"!

Vimberg[2] constructed RBSs by changing enhancer sequence and SD length (fig.2). Although SD length was changed, there wasn't big difference in translation efficiency among RBSs' without enhancer (fig.3). But big difference appeared in enhancer RBSs when SD length was changed (fig.4). Strong SDs are stimulated and weak SDs are repressed by A/U rich enhancer.

fig.2: Various enhancer and SD. Vimberg combined 3 enhancers and 10 SDs and measured GFP expression.
fig.3: GFP expression in No enhancer RBSs.
fig.4: GFP expression in A/U rich RBSs.

We decided to constructed 4 new RBSs based on Vimberg. These RBSs have A/U rich enhancer. To change the translation efficiencies we varied the length of SD sequence.

  1. B. S. Laursen, H. P. Sørensen, et al. Initiation of Protein Synthesis in Bacteria (2005) Microbiol. Mol. Biol. Rev.
  2. V. Vimberg, A. Tats, et al. Translation initiation region sequence preferences in Escherichia coli (2007) BMC Molecular Biology