Team:Peking/Project/BioSensors/XylS

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<a href="https://2013.igem.org/Team:Peking">home</a>
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<a href="https://2013.igem.org/Team:Peking">Home</a>
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<li><a>Plug-ins & Expansion</a></li>
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<li><a>Item2</a></li>
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                                <li><a href="https://2013.igem.org/Team:Peking/Model">Band-pass Filter</a></li>
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<li><a>Item3</a></li>
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                                <li><a href="https://2013.igem.org/Team:Peking/ModelforFinetuning">Biosensor Fine-tuning</a></li>
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</ul>
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                        <li id="PKU_navbar_HumanPractice" class="Navbar_Item" style="width:90px">
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<a href="">Data page</a>
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                                <li><a href="https://2013.igem.org/Team:Peking/DataPage/Parts">Parts</a></li>
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<li><a href="https://2013.igem.org/Team:Peking/DataPage/JudgingCriteria">Judging Criteria</a></li>
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<a href="https://2013.igem.org/Team:Peking/HumanPractice">Human Practice</a>
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                                <li><a href="https://2013.igem.org/Team:Peking/HumanPractice/Questionnaire">Questionnaire Survey</a></li>
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<li><a href="https://2013.igem.org/Team:Peking/HumanPractice/FactoryVisit">Visit and Interview</a></li>
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                                <li><a href="https://2013.igem.org/Team:Peking/HumanPractice/ModeliGEM">Practical Analysis</a></li>
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<li><a href="https://2013.igem.org/Team:Peking/HumanPractice/iGEMWorkshop">Team Communication</a></li>
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<div id="ProjectTitle">
<div id="ProjectTitle">
<h1 id="ProjectName">Biosensors</h1>
<h1 id="ProjectName">Biosensors</h1>
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                <h1 id="ProjectSubname">A FAST, EASY AND ACCURATE METHOD TO DETECT TOXIC AROMATIC COMPOUNDS</h1>
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                 <img src="https://static.igem.org/mediawiki/igem.org/9/96/Peking2013-biosensortitile-zyh.jpg"/>
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                 <h1 id="SensorsListTitle"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors">Biosensors</a></h1>
                 <h1 id="SensorsListTitle"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors">Biosensors</a></h1>
                 <ul id="SensorsList">
                 <ul id="SensorsList">
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/CapR">CapR</a><li>
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                     <li class="SensorsListItem" style="font-size:18px; height:15px; width:180px; position:relative; left:-10px;">Individual Biosensors<li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/DmpR">DmpR</a><li>
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                    <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/XylS">XylS</a><li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/HbpR">HbpR</a><li>
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                     <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/XylR">XylR</a><li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/HcaR">HcaR</a><li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/NahR">NahR</a><li>
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                     <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/HpaR">HpaR</a><li>
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                     <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/HpaR#ContentHpaR4">PaaX</a><li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/XylR">XylR</a><li>
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                     <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/DmpR">DmpR</a><li>
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                     <li><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/XylS">XylS</a><li>
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                     <li class="SensorsListItem"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/NahR">NahR</a><li>
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                     <li class="SensorsListItem" style="font-size:18px; height:40px; width:180px; position:relative; left:-10px; top:25px;"><a href="https://2013.igem.org/Team:Peking/Project/BioSensors/MulticomponentAnalysis">Multi-component Analysis</a></li>
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         <div >
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             <h1 id="PageTitle">XylS</h1>
             <h1 id="PageTitle">XylS</h1>
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             <h2 id="OverviewXylS1"> Overview </h2>
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             <h2 id="OverviewXylS1"> Mechanism </h2>
             <h3 id="OverviewXylS2"> Build Our Own Sensor! </h2>
             <h3 id="OverviewXylS2"> Build Our Own Sensor! </h2>
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<img id="XylSFigure2" src="https://static.igem.org/mediawiki/igem.org/6/66/Peking2013_Xyls_figure2.png"/>
<img id="XylSFigure2" src="https://static.igem.org/mediawiki/igem.org/6/66/Peking2013_Xyls_figure2.png"/>
<img id="XylSFigure3" src="https://static.igem.org/mediawiki/igem.org/a/a3/Peking2013_Xyls_figure3.png"/>
<img id="XylSFigure3" src="https://static.igem.org/mediawiki/igem.org/a/a3/Peking2013_Xyls_figure3.png"/>
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<img id="XylSFigure4" src="https://static.igem.org/mediawiki/igem.org/6/68/Peking2013_Xyls_figure4.png"/>
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<img id="XylSFigure4" src="https://static.igem.org/mediawiki/2013/4/43/Peking2013_XylR_figure4.PNG"/>
<img id="XylSFigure5_1" src="https://static.igem.org/mediawiki/igem.org/f/f4/Peking2013_Xyls_figure5.1.png"/>
<img id="XylSFigure5_1" src="https://static.igem.org/mediawiki/igem.org/f/f4/Peking2013_Xyls_figure5.1.png"/>
<img id="XylSFigure5_2" src="https://static.igem.org/mediawiki/igem.org/a/a4/Peking2013_Xyls_figure5.2.PNG"/>
<img id="XylSFigure5_2" src="https://static.igem.org/mediawiki/igem.org/a/a4/Peking2013_Xyls_figure5.2.PNG"/>
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<img id="XylSFigure6" src="https://static.igem.org/mediawiki/igem.org/9/93/Peking2013_Xyls_figure6.png"/>
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<img id="XylSFigure6" src="https://static.igem.org/mediawiki/2013/5/5f/Peking2013_XylS_Figure6.PNG"/>
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<img id="XylSFigure7" src="https://static.igem.org/mediawiki/igem.org/6/67/Peking2013_Xyls_figur7.png"/>
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<p id="ContentXylS1">
<p id="ContentXylS1">
-
XylS is an archetype transcriptional activator of AraC/XylS family, mined from the TOL plasmid pWW0 of the bacterium Pseudomonas putida. It is composed of a C-terminal domain (CTD) involved in DNA binding containing two helix-turn-helix motifs and an N-terminal domain required for effector binding and protein dimerization[5].<br/>XylS detect benzoate and its’ derivatives, mainly methyl and chlorine substitutes at 2-, 3- carbon[4] .
+
XylS is an archetype transcriptional activator of AraC/XylS family, mined from the TOL plasmid pWW0 of the bacterium <i>Pseudomonas putida</i>. It is composed of a C-terminal domain (CTD) involved in DNA binding, and an N-terminal domain required for effector binding and protein dimerization<a href="#FigureXylS7"><sup>[1]</sup></a>. XylS detect benzoate and its derivatives, mainly methyl and chlorine substitution at 2-, 3- carbon<a href="#FigureXylS7"><sup>[2]</sup></a>.
</p>
</p>
<p id="ContentXylS2">
<p id="ContentXylS2">
-
On TOL plasmid, the expression of XylS is initiated from two promoters. The strong promoter Ps1 which depends on factor is positively regulated by XylR at the presence of toluene. Ps2, which depends on factor, is constitutive but weak[7]. <br/>
+
On TOL plasmid, the expression of XylS is initiated at two promoters: the strong promoter <i>Ps1</i> that is &sigma;<sup>54</sup>-dependent is positively regulated by XylR in the presence of toluene; <i>Ps2</i>, a &sigma;<sup>70</sup>-dependent promoter, is constitutive but weaker<a href="#FigureXylS7"><sup>[3]</sup></a>.  
-
The cognate promoter regulated by XylS, Pm, is 70-dependent in E.coli, while in Pseudomonas putida, it is 32/38-dependent[6]. It acts as the master regulator to control the ON/OFF expression of meta-operon on TOL plasmid pWW0[2]. In this meta-operon, XylXYZLTEGFJQKIH genes encode enzymes for the degradation of benzoate and its derivatives, generating intermediate products in TCA cycle. (Fig 1)
+
<br/><br/>
 +
The cognate promoter regulated by XylS, <i>Pm</i>, is &sigma;<sup>54</sup>-dependent in <i>Pseudomonas putida</i>; meanwhile in <i>E.coli</i>, it is &sigma;<sup>70</sup>-dependent<a href="#FigureXylS7"><sup>[5]</sup></a>. It acts as the master regulator to control the ON/OFF expression of meta-operon on TOL plasmid pWW0<a href="#FigureXylS7"><sup>[6]</sup></a>. In this meta-operon, <I>xylXYZLTEGFJQKIH</I> genes encode enzymes for the degradation of benzoate and its derivatives, producing intermediate metabolites as carbon sources (<b>Fig.1</b>).
 +
 
</p>
</p>
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<p id="ContentXylS3">
<p id="ContentXylS3">
-
XylS recognizes two 15-bp direct repeats (TGCA-N6-GGNTA) on Pm promoter, each consisting of two half-sites: box A1/A2 (TGCA) and box B1/B2 (GGNTA). The arrangement of the two repeats is deposited like this so that the proximal XylS binding site overlaps the RNA polymerase -35 binding box by 2 bp[3]. (Fig 2)
+
XylS recognizes two 15-bp repeats (TGCA-N6-GGNTA) in <i>Pm</i> promoter, each featured by box A1/A2 (TGCA) and box B1/B2 (GGNTA), respectively. The arrangement of the two repeats is deposited as shown in <b>Figure 2</b>; the proximal XylS binding site overlaps the -35 box by 2 bp (the sequence for the binding of RNA polymerase)<a href="#FigureXylS7"><sup>[4]</sup></a>.
</p>
</p>
<p id="ContentXylS4">
<p id="ContentXylS4">
-
The process of Pm activation includes XylS-dependent DNA bending, XylS dimerization[3] and RNAP recruitment. Binding of effector molecule (e.g., benzoate anion) to XylS N-terminal domain causes the conformational change of C-terminal domain, which is released from inhibition[3], thus enabling XylS protein to bind Pm promoter on upstream activated sequence. The binding of XylS to DNA and accompanied DNA bending is a sequential process: A first XylS monomer binds to Pm at the proximal site with a bending angle to 50°. This DNA bending facilitates the binding of a second monomer at the distal site, increasing the DNA curvature up to 98°. This allows the formation of ready-to-use XylS dimer at Pm promoter. It is widely speculated that the XylS dimer recruits RNAP through contact with  subunit and -CTD (C-terminal domain of  subunit), thus to allow following open complex formation at -10 region and transcription is initiated[1].(Fig 3.)
+
<br/><br/>
 +
The process of <i>Pm</i> activation includes XylS-dependent DNA bending, XylS dimerization<a href="#FigureXylS7"><sup>[4]</sup></a> and RNA polymerase (RNAP) recruitment. Binding of effector molecule (e.g., benzoate anion) to XylS N-terminal domain causes the conformational change at the C-terminal domain, which enables XylS protein to bind to upstream activated sequence of <i>Pm</i> promoter. This allows the formation of ready-to-use XylS dimer at <i>Pm</i> promoter. See <b>Figure 3</b> for detailed explanation on the mechanism of transcription initiation by XylS.
 +
<br/><br/>
 +
 
 +
Since one of the criteria of our <a href="https://2013.igem.org/Team:Peking/Project/SensorMining">Sensor Mining</a> for aromatics-sensing transcriptional regulators is "well-studied", it can be expected that some mutants of XylS with novel aromatics-sensing characteristics have been identified in previous studies. As expected, according to the information we collected, there are three groups of XylS mutants. The first group, featured by thr45, includes a XylS mutant that exhibits broader aromatics-sensing profile than wild-type XylS, as well as higher level of transcription activation; this mutant are able to sense the ordinarily non-inducer 4-ethylbenzoate. The second group, featured by leu88 mutation, exhibits constitutive expression from the <i>Pm</i> promoter in the absence of inducers. The third group of mutants, including gly152, his41, val288, phe155, or arg256 mutations, recognizes new inducers, but generally with low induction fold.
 +
<br/><br/>
 +
 
 +
See <b>Table 1</b> for the comprehensive summary of XylS mutants and accompanied novel aromatics-sensing characteristics<a href="#FigureXylS7"><sup>[2]</sup></a>, which provides a rich repertoire for the synthetic biologists to customize the aromatics-sensing characteristics of XylS protein.  
 +
 
</p>
</p>
<p id="ContentXylS5">
<p id="ContentXylS5">
-
Various mutants of XylS are recognized, and they are divided into three groups. The first group, consisting of thr45, includes XylS mutant that exhibits broader detective range than XylS wild type as well as mediating high level reporter expression. This mutant recognizes the ordinary non-effectors salycilate and 4-ethylbenzoate. The second group, consisting of mutant leu88, exhibits constitutive expression from Pm promoter in the absence of inducers. The third group of mutants, including gly152, his41, val288, phe155, arg256, recognize new inducers, but differ from group one in that their induction ratio with new inducers are generally low, and the response to wild type inducers in some cases is reduced, even absent . For example, mutant gly152 is activated by new inducers 2-, 3- and 4-methoxybenzoate, but not by 2-fluorobenzoate and only weakly by methylbenzoates that are activators for wild type XylS. Mutant his41 is strongly activated by 5mM 3-methoxybenzoate, but it doesn't recognize the usual inducers 2- and 4-fluoro-3-iodo-, 3,4-dimethyl- and 3,4-dichlorobenzoate[4]. (Table 1)
+
 
</p>
</p>
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<p id="ContentXylS6">
<p id="ContentXylS6">
-
2013 Peking iGEM team adopted thr45 XylS mutant and obtained the coding sequence via synthesis. We constructed Pm/XylS expression system using sfGFP as reporter gene, XylS is constitutively expressed under the control of Pc promoter, and the expression of sfGFP is positively regulated by XylS at the presence of inducers. In this system, the strength of Pc promoter and RBS in front of sfGFP coding sequence is manipulated. In order to obtain better response performance, we contructed Pc library containing Pc of different strength, thus controlling the amount of XylS protein.
+
Peking iGEM team has adopted thr45 XylS mutant (for the convenient of reading, referred to as “XylS" below) to build a biosensor due to its broader aromatics-sensing profile with high induction ratio. As discussed in <a href="https://2013.igem.org/Team:Peking/Project/BioSensors#BiosensorContent1">Biosensor Introduction</a>, we constructed a <i>Pm</i>/XylS biosensor circuit using eGFP as reporter gene. XylS is constitutively expressed under the control of a constitutive promoter (<i>Pc</i>), and the expression of eGFP is positively regulated by XylS in the presence of inducers. In this circuit, the strength of <i>Pc</i> promoter and RBS sequence preceding XylS and eGFP were manipulated, respectively, to fine-tune the performance.
-
<br/>
+
 
-
From On/Off test via ELIZA following test protocol 1 we found the Pm/XylS expression system adopting Pc promoter J23114 has the highest induction ratio when exposed to natural inducers (Fig 4.).   
+
Through <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">ON/OFF test</a> following <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">Test Protocol 1</a>, we found the biosensor circuit adopting a weak constitutive promoterJ23114, has the highest induction ratio when exposed to the inducers (<b>Fig.4</b>).   
 +
</p>
</p>
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<p id="ContentXylS7">
<p id="ContentXylS7">
-
XylS strain with no inducer showed low basal expression of sfGFP, and 20compounds showed apparent activation effect with the induction ratios over 20 (Fig 5), they are listed as follows: BzO, 2-MeBzO, 3-MeBzO, 4-MeBzO, 2-FBzO, 4-FBzO, 2-ClBzO, 3-ClBzO, 4-ClBzO, 2-BrBzO, 4-BrBzO, 3-IBzO, 3-MeOBzO, SaA, 3-MeOSaA, 4-ClSaA, 5-ClSaA, 3-MeBAD, 3-ClTOL  
+
XylS biosensor treated with no inducer showed negligible basal expression of sfGFP. 20 compounds showed apparent activation effects with high induction ratios (higher than 20; <b>Fig.5</b>). They are BzO, 2-MeBzO, 3-MeBzO, 4-MeBzO, 2-FBzO, 4-FBzO, 2-ClBzO, 3-ClBzO, 4-ClBzO, 2-BrBzO, 4-BrBzO, 3-IBzO, 3-MeOBzO, SaA, 3-MeOSaA, 4-ClSaA, 5-ClSaA, 3-MeBAD, and 3-ClTOL (<a href="https://static.igem.org/mediawiki/igem.org/2/24/Peking2013_Chemicals_V3%2B.pdf">Click Here</a> for the full names of aromatic compounds).
-
(Fig 5.)(click here for full name).  
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</p>
</p>
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<p id="ContentXylS8">
<p id="ContentXylS8">
-
After construction of well-tuned expression system, Pm/J23114-XylS expression system was subjected to induction experiments with concentration of inducer ranging at 10 µM, 30µM, 100µM, 300µM and 1000µM according to protocol 1. The results showed along with the raise of inducer concentration, the induction ratio rises (Fig 6.).
+
Moreover, we examined the dose-response curves of effective inducers for more details. Induction experiments using different sets of inducer concentrations (10 µM, 30µM, 100µM, 300µM and 1000µM) were performed following <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">Test Protocol 1</a>. The results showed that the dose-response curves appeared like Hill functions (<b>Fig.6, Fig.7</b>).  
-
 
+
         </p>
         </p>
<p id="ContentXylS9">
<p id="ContentXylS9">
-
We induced Pm/J23114-XylS expression system with 78 types of aromatic compounds, and found that salicylic acid and its’ derivatives are also inducers of XylS which is not reported in previous work (Fig 7.).  
+
Checking the aromatics-sensing profile of XylS biosensor, we found that salicylic acid and its derivatives are also inducers of XylS which has <b>not been reported in previous studies</b>. The dose-response curves are illustrated in <b>Figure 7</b>.  
-
 
+
</br></br>
 +
These results altogether show that XylS biosensor has high induction ratio, low basal level and aromatics-specific sensing profile, which makes it to be a really high-performance component of our biosensor toolkit.
         </p>
         </p>
          
          
-
        <p id="FigureXylS1">
+
<p id="FigureXylS1">
-
Fig 1. Regulatory circuits controlling expression from the TOL plasmid pWW0[7].  
+
<B>Figure 1.</B> Regulatory circuits controlled by XylS and XylR on the TOL plasmid pWW0<a href="#FigureXylS7"><sup>[3]</sup></a>.  
-
Squares: XylS; circles: XylR; open symbols: transcriptional regulator forms unable to stimulate transcription; closed symbols: forms able to stimulate transcription. The regulatory loops are explained in the text.  
+
Symbols used in this figure: Squares, XylS; circles, XylR; open symbols, transcriptional regulator without aromatic effector binding; closed symbols, effector-bound transcription factors that is in active form. See the main text for the detailed explanation for the regulatory loops<a href="#FigureXylS7"><sup>[4]</sup></a>.
</p>
</p>
<p id="FigureXylS2">
<p id="FigureXylS2">
-
The orange arrows indicate the two XylS binding sites (proximal and distal), each composed of conserved A1/A2 and B1/B2 boxes. The -10 and -35 hexamers are in blue. A right-angled arrow indicates the transcription initiation site.
+
<B>Figure 2. </B> Sequence features  of <i>Pm</i> promoter<a href="#FigureXylS7"><sup>[4]</sup></a>
 +
The orange arrows indicate the two XylS binding sites (proximal and distal), each consisting of conserved A1/A2 and B1/B2 boxes. The -10 and -35 hexamers are in blue. A right-angled arrow indicates the transcription start site (+1).
</p>
</p>
<p id="FigureXylS3">
<p id="FigureXylS3">
-
Step 1: Free DNA. The 10/ 35 RNAP binding site and the two XylS binding sites (D: distal; and P: proximal) are depicted. The bending angle is 35°, centered in the XylS proximal binding site. Step 2: A first XylS monomer binds Pm at the proximal site, shifts the bent center to DNA sequence between the two sites, and increases the bending angle to 50°. Step 3: This change favors binding of a second monomer at the distal site, further increasing the DNA curvature to an overall value of 98° (here schematized as a right angle). Contacts are established with RNAP through the α-CTD and probably with the σ-subunit, which as shown in Step 4 favors open complex formation and transcription initiation.
+
<B>Figure 3. </B> Mechanism of transcription activation by XylS at <i>Pm</i> promoter. Step 1: Free DNA. The -10/-35 consensus boxes of &sigma;<sup>70</sup>-dependent promoter and the two XylS binding sites (D: distal; and P: proximal) are highlighted. The bending angle is supposed to be 35°, centered at XylS proximal binding site. Step 2: A first XylS monomer is enabled to bind to <i>Pm</i> at the proximal site after binding with inducer at N terminal, shifting the bent center to the DNA sequence between the two XylS binding sites, increasing the bending angle to 50°. Step 3: This conformational change facilitates the binding of a second ready-to-use XylS monomer to the distal site, further increasing the DNA curvature to an overall value of 98°. Step 4: Contacts with RNAP, also probably with the σ-subunit, are established through the α-CTD of RNA polymerase, which dramatically facilitates the open complex formation and transcription initiation.
</p>
</p>
<p id="FigureXylS4">
<p id="FigureXylS4">
-
Fig 4. Induction ratio of Pc promoter library. X-axis stands for distinct expression system with different Pc promoter. The expression intensity of promoters, J23113, J23109, J23114, J23105, J23106 is 21, 106, 256, 623, and 1185 respectively. Four kinds of inducers, namely BzO, 2-MeBzO, 3-MeBzO and 4-MeBzO shown with different color squares were tested following test protocol 1 via flow cytometry. Y-axis represents induction ratio reflected via fluorescence intensity. The Pm/XylS expression system which adopted Pc promoter J23114 clearly performed best of all of the four inducers.  
+
<B>Figure 4.</B>Using a library of constitutive promoters (<i>Pc</i>) to fine-tune the induction ratio of XylS biosensor. Horizontal axis stands for different XylS biosensor circuits with different <i>Pc</i> promoters. These <i>Pc</i> promoters are of different strength to control the expression of XylS. The relative expression strength of these constitutive promoters, J23113, J23109, J23114, J23105, J23106 are 21, 106, 256, 623, and 1185, respectively, according to the <a href="http://parts.igem.org/Part:BBa_J23119">Partsregistry</a>. Four kinds of aromatic compounds, namely BzO, 2-MxeBzO, 3-MeBzO and 4-MeBzO, shown with different color intensities, were tested following <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">Test Protocol 1</a>. Vertical axis represents the ON-OFF induction ratio. The <i>Pm</i>/XylS biosensor circuit adopting a weak <i>Pc</i> promoter J23114 performed best throughout the four inducers.  
</p>
</p>
<p id="FigureXylS5">
<p id="FigureXylS5">
-
Fig 5. The detective range of Pm/J23114-XylS expression system.
+
<B>Figure 5.</B> (<b>a</b>) The induction ratios of all 78 typical aromatic compounds in the <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">ON/OFF test</a> following <a href="https://2013.igem.org/Team:Peking/Team/Notebook/Protocols">Test Protocol 1</a>. XylS biosensor could respond to 24 out of 78 aromatics with the induction ratio higher than 20, mainly benzoate, salicylic and their derivatives. (<b>b</b>) The aromatics-sensing profile of XylS biosensor is summarized from (<b>a</b>), highlighted in red in the aromatics spectrum. The structure formula of typical inducers are listed around the central spectrum, near their chemical formula.  
-
(a) The induction ratio column in the On-Off test following protocol 1. XylS could respond to 24 out of 78 aromatics with the induction ratio over 20, mainly benzoate, salicylic and their derivatives. (b) The detection range of sensor strain XylS is profiled in red at the aromatics spectrum. The structure formula of typical inducer is listed around the cycle spectrum, near its chemical formula.  
+
-
 
+
</p>
</p>
<p id="FigureXylS6">
<p id="FigureXylS6">
-
Fig 6. Dose-response curve of Pm/J23114-XylS expression system in response to benzoate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Different colors represent different kinds of inducers. Y-axis shows induction ratio reflected via fluorescence intensity.  
+
<B>Figure 6.</B>Dose-response curves of XylS biosensor induced by benzoate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Different colors represent different kinds of inducers. Y-axis shows induction ratios. The induction ratio was calculated by dividing the fluorescence intensity of biosensor exposed to object inducers by the basal fluorescence intensity of the biosensor itself.
</p>
</p>
<p id="FigureXylS7">
<p id="FigureXylS7">
-
Fig 7. Dose-response curve of Pm/J23114-XylS expression system in response to salicylate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Different colors represent different kinds of inducers. Y-axis shows induction ratio reflected via fluorescence intensity.  
+
<B>Figure 7.</B> Dose-response curves of XylS biosensor induced by salicylate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Y-axis denotes induction ratios. Different colors denote different kinds of inducers. The induction ratio was calculated by dividing the fluorescence intensity of biosensor exposed to object inducers by the basal fluorescence intensity of the biosensor itself.
</p>
</p>
        
        
Line 409: Line 438:
<p id="ReferenceXylS">
<p id="ReferenceXylS">
-
REFERENCES:
+
REFERENCES:<br/>
-
[1] Domínguez-Cuevas, P., Ramos, J. L., & Marqués, S. (2010). Sequential XylS-CTD binding to the Pm promoter induces DNA bending prior to activation. Journal of bacteriology, 192(11), 2682-2690.
+
[1] Kaldalu, N., Toots, U., de Lorenzo, V., & Ustav, M. (2000). Functional domains of the TOL plasmid transcription factor XylS. Journal of bacteriology, 182(4), 1118-1126.<br/>
-
[2] Kaldalu, N., Mandel, T., & Ustav, M. (1996). TOL plasmid transcription factor XylS binds specifically to the Pm operator sequence. Molecular microbiology,20(3), 569-579.
+
[2] Ramos, J. L., Michan, C., Rojo, F., Dwyer, D., & Timmis, K. (1990). Signal-regulator interactions, genetic analysis of the effector binding site of xyls, the benzoate-activated positive regulator of Pseudomonas TOL plasmid meta-cleavage pathway operon. Journal of molecular biology, 211(2), 373-382.<br/>
-
[3] Domínguez-Cuevas, P., Marín, P., Busby, S., Ramos, J. L., & Marqués, S. (2008). Roles of effectors in XylS-dependent transcription activation: intramolecular domain derepression and DNA binding. Journal of bacteriology, 190(9), 3118-3128.
+
[3] Ramos, J. L., Marqués, S., & Timmis, K. N. (1997). Transcriptional control of the Pseudomonas TOL plasmid catabolic operons is achieved through an interplay of host factors and plasmid-encoded regulators. Annual Reviews in Microbiology, 51(1), 341-373.<br/>
-
[4] Ramos, J. L., Michan, C., Rojo, F., Dwyer, D., & Timmis, K. (1990). Signal-regulator interactions, genetic analysis of the effector binding site of xyls, the benzoate-activated positive regulator of Pseudomonas TOL plasmid meta-cleavage pathway operon. Journal of molecular biology, 211(2), 373-382.
+
[4] Domínguez-Cuevas, P., Marín, P., Busby, S., Ramos, J. L., & Marqués, S. (2008). Roles of effectors in XylS-dependent transcription activation: intramolecular domain derepression and DNA binding. Journal of bacteriology, 190(9), 3118-3128.<br/>
-
[5] Kaldalu, N., Toots, U., de Lorenzo, V., & Ustav, M. (2000). Functional domains of the TOL plasmid transcription factor XylS. Journal of bacteriology, 182(4), 1118-1126.
+
[5] Gerischer, U. (2002). Specific and global regulation of genes associated with the degradation of aromatic compounds in bacteria. Journal of molecular microbiology and biotechnology, 4(2), 111-122.<br/>
-
[6] Gerischer, U. (2002). Specific and global regulation of genes associated with the degradation of aromatic compounds in bacteria. Journal of molecular microbiology and biotechnology, 4(2), 111-122.
+
[6] Kaldalu, N., Mandel, T., & Ustav, M. (1996). TOL plasmid transcription factor XylS binds specifically to the Pm operator sequence. Molecular microbiology,20(3), 569-579.<br/>
-
[7] Ramos, J. L., Marqués, S., & Timmis, K. N. (1997). Transcriptional control of the Pseudomonas TOL plasmid catabolic operons is achieved through an interplay of host factors and plasmid-encoded regulators. Annual Reviews in Microbiology, 51(1), 341-373.
+
[7] Domínguez-Cuevas, P., Ramos, J. L., & Marqués, S. (2010). Sequential XylS-CTD binding to the Pm promoter induces DNA bending prior to activation. Journal of bacteriology, 192(11), 2682-2690. <br/>
 +
 
 +
 
 +
 
 +
 
 +
 
 +
 
</p>
</p>
 +
 +
<h1 id="XylSTableTitle"><b>Table 1. Comprehensive summary of XylS mutants and accompanied aromatics-sensing characteristics.</b></h1>
 +
<table border="1" id="XylSTable">
 +
<tr>
 +
  <th>Groups</th>
 +
  <th>Mutations</th>
 +
  <th>Expected Aromatics-sensing Profiles</th>
 +
</tr>
 +
<tr>
 +
  <td>Broader aromatics-sensing profiles with high induction ratio</td>
 +
  <td>Arg<sup>45</sup><Code>&rarr;</Code>Thr</td>
 +
  <td>SaA; 4-EtBzO; BzO; 2-MeBzO; 4-MeBzO</td>
 +
</tr>
 +
<tr>
 +
  <td>Constitutive <i>Pm</i> promoter activation</td>
 +
  <td>Trp<sup>88</sup><Code>&rarr;</Code>Leu</td>
 +
  <td>Not mentioned, this mutant causes constitutive expression of <i>Pm</i> promoter</td>
 +
</tr>
 +
<tr>
 +
  <td rowspan="5">Broader aromatics-sensing profiles with lower induction ratios</td>
 +
  <td>Arg<sup>152</sup><Code>&rarr;</Code>Gly</td>
 +
  <td>BzO; 2-MeBzO; 2-,3-ClBzO; 2-,3- and 4-MeOBzO</td>
 +
</tr>
 +
<tr>
 +
  <td>Arg<sup>41</sup><Code>&rarr;</Code>His</td>
 +
  <td>BzO; 3-MeBzO; 3-ClBzO; 3-BrBzO; 3-MeOBzO</td>
 +
</tr>
 +
<tr>
 +
  <td>Asp<sup>288</sup><Code>&rarr;</Code>Val</td>
 +
  <td>BzO; 3-MeBzO; 4-MeOBzO; 4-BrBzO; 2,4-MeBzO; 2,5-MeBzO; 3-ClBzO</td>
 +
</tr>
 +
<tr>
 +
  <td>Leu<sup>155</sup><Code>&rarr;</Code>Phe</td>
 +
  <td>2-MeBzO; 3-MeBzO; 4-MeBzO; 2,5-MeBzO, 4-ClBzO</td>
 +
</tr>
 +
<tr>
 +
  <td>Pro<sup>256</sup><Code>&rarr;</Code>Arg</td>
 +
  <td>BzO; 2-MeBzO; 3-MeBzO; 3,5-MeBzO; 3,5-ClBzO</td>
 +
</tr>
 +
</table>
  </div>
  </div>

Latest revision as of 18:13, 28 October 2013

Biosensors

XylS

Mechanism

Build Our Own Sensor!

XylS is an archetype transcriptional activator of AraC/XylS family, mined from the TOL plasmid pWW0 of the bacterium Pseudomonas putida. It is composed of a C-terminal domain (CTD) involved in DNA binding, and an N-terminal domain required for effector binding and protein dimerization[1]. XylS detect benzoate and its derivatives, mainly methyl and chlorine substitution at 2-, 3- carbon[2].

On TOL plasmid, the expression of XylS is initiated at two promoters: the strong promoter Ps1 that is σ54-dependent is positively regulated by XylR in the presence of toluene; Ps2, a σ70-dependent promoter, is constitutive but weaker[3].

The cognate promoter regulated by XylS, Pm, is σ54-dependent in Pseudomonas putida; meanwhile in E.coli, it is σ70-dependent[5]. It acts as the master regulator to control the ON/OFF expression of meta-operon on TOL plasmid pWW0[6]. In this meta-operon, xylXYZLTEGFJQKIH genes encode enzymes for the degradation of benzoate and its derivatives, producing intermediate metabolites as carbon sources (Fig.1).

XylS recognizes two 15-bp repeats (TGCA-N6-GGNTA) in Pm promoter, each featured by box A1/A2 (TGCA) and box B1/B2 (GGNTA), respectively. The arrangement of the two repeats is deposited as shown in Figure 2; the proximal XylS binding site overlaps the -35 box by 2 bp (the sequence for the binding of RNA polymerase)[4].



The process of Pm activation includes XylS-dependent DNA bending, XylS dimerization[4] and RNA polymerase (RNAP) recruitment. Binding of effector molecule (e.g., benzoate anion) to XylS N-terminal domain causes the conformational change at the C-terminal domain, which enables XylS protein to bind to upstream activated sequence of Pm promoter. This allows the formation of ready-to-use XylS dimer at Pm promoter. See Figure 3 for detailed explanation on the mechanism of transcription initiation by XylS.

Since one of the criteria of our Sensor Mining for aromatics-sensing transcriptional regulators is "well-studied", it can be expected that some mutants of XylS with novel aromatics-sensing characteristics have been identified in previous studies. As expected, according to the information we collected, there are three groups of XylS mutants. The first group, featured by thr45, includes a XylS mutant that exhibits broader aromatics-sensing profile than wild-type XylS, as well as higher level of transcription activation; this mutant are able to sense the ordinarily non-inducer 4-ethylbenzoate. The second group, featured by leu88 mutation, exhibits constitutive expression from the Pm promoter in the absence of inducers. The third group of mutants, including gly152, his41, val288, phe155, or arg256 mutations, recognizes new inducers, but generally with low induction fold.

See Table 1 for the comprehensive summary of XylS mutants and accompanied novel aromatics-sensing characteristics[2], which provides a rich repertoire for the synthetic biologists to customize the aromatics-sensing characteristics of XylS protein.

Peking iGEM team has adopted thr45 XylS mutant (for the convenient of reading, referred to as “XylS" below) to build a biosensor due to its broader aromatics-sensing profile with high induction ratio. As discussed in Biosensor Introduction, we constructed a Pm/XylS biosensor circuit using eGFP as reporter gene. XylS is constitutively expressed under the control of a constitutive promoter (Pc), and the expression of eGFP is positively regulated by XylS in the presence of inducers. In this circuit, the strength of Pc promoter and RBS sequence preceding XylS and eGFP were manipulated, respectively, to fine-tune the performance. Through ON/OFF test following Test Protocol 1, we found the biosensor circuit adopting a weak constitutive promoter, J23114, has the highest induction ratio when exposed to the inducers (Fig.4).

XylS biosensor treated with no inducer showed negligible basal expression of sfGFP. 20 compounds showed apparent activation effects with high induction ratios (higher than 20; Fig.5). They are BzO, 2-MeBzO, 3-MeBzO, 4-MeBzO, 2-FBzO, 4-FBzO, 2-ClBzO, 3-ClBzO, 4-ClBzO, 2-BrBzO, 4-BrBzO, 3-IBzO, 3-MeOBzO, SaA, 3-MeOSaA, 4-ClSaA, 5-ClSaA, 3-MeBAD, and 3-ClTOL (Click Here for the full names of aromatic compounds).

Moreover, we examined the dose-response curves of effective inducers for more details. Induction experiments using different sets of inducer concentrations (10 µM, 30µM, 100µM, 300µM and 1000µM) were performed following Test Protocol 1. The results showed that the dose-response curves appeared like Hill functions (Fig.6, Fig.7).

Checking the aromatics-sensing profile of XylS biosensor, we found that salicylic acid and its derivatives are also inducers of XylS which has not been reported in previous studies. The dose-response curves are illustrated in Figure 7.

These results altogether show that XylS biosensor has high induction ratio, low basal level and aromatics-specific sensing profile, which makes it to be a really high-performance component of our biosensor toolkit.

Figure 1. Regulatory circuits controlled by XylS and XylR on the TOL plasmid pWW0[3]. Symbols used in this figure: Squares, XylS; circles, XylR; open symbols, transcriptional regulator without aromatic effector binding; closed symbols, effector-bound transcription factors that is in active form. See the main text for the detailed explanation for the regulatory loops[4].

Figure 2. Sequence features of Pm promoter[4] The orange arrows indicate the two XylS binding sites (proximal and distal), each consisting of conserved A1/A2 and B1/B2 boxes. The -10 and -35 hexamers are in blue. A right-angled arrow indicates the transcription start site (+1).

Figure 3. Mechanism of transcription activation by XylS at Pm promoter. Step 1: Free DNA. The -10/-35 consensus boxes of σ70-dependent promoter and the two XylS binding sites (D: distal; and P: proximal) are highlighted. The bending angle is supposed to be 35°, centered at XylS proximal binding site. Step 2: A first XylS monomer is enabled to bind to Pm at the proximal site after binding with inducer at N terminal, shifting the bent center to the DNA sequence between the two XylS binding sites, increasing the bending angle to 50°. Step 3: This conformational change facilitates the binding of a second ready-to-use XylS monomer to the distal site, further increasing the DNA curvature to an overall value of 98°. Step 4: Contacts with RNAP, also probably with the σ-subunit, are established through the α-CTD of RNA polymerase, which dramatically facilitates the open complex formation and transcription initiation.

Figure 4.Using a library of constitutive promoters (Pc) to fine-tune the induction ratio of XylS biosensor. Horizontal axis stands for different XylS biosensor circuits with different Pc promoters. These Pc promoters are of different strength to control the expression of XylS. The relative expression strength of these constitutive promoters, J23113, J23109, J23114, J23105, J23106 are 21, 106, 256, 623, and 1185, respectively, according to the Partsregistry. Four kinds of aromatic compounds, namely BzO, 2-MxeBzO, 3-MeBzO and 4-MeBzO, shown with different color intensities, were tested following Test Protocol 1. Vertical axis represents the ON-OFF induction ratio. The Pm/XylS biosensor circuit adopting a weak Pc promoter J23114 performed best throughout the four inducers.

Figure 5. (a) The induction ratios of all 78 typical aromatic compounds in the ON/OFF test following Test Protocol 1. XylS biosensor could respond to 24 out of 78 aromatics with the induction ratio higher than 20, mainly benzoate, salicylic and their derivatives. (b) The aromatics-sensing profile of XylS biosensor is summarized from (a), highlighted in red in the aromatics spectrum. The structure formula of typical inducers are listed around the central spectrum, near their chemical formula.

Figure 6.Dose-response curves of XylS biosensor induced by benzoate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Different colors represent different kinds of inducers. Y-axis shows induction ratios. The induction ratio was calculated by dividing the fluorescence intensity of biosensor exposed to object inducers by the basal fluorescence intensity of the biosensor itself.

Figure 7. Dose-response curves of XylS biosensor induced by salicylate and its derivatives. X-axis stands for concentration gradient of inducers at 10µM, 30µM, 100µM, 300µM and 1000µM. Y-axis denotes induction ratios. Different colors denote different kinds of inducers. The induction ratio was calculated by dividing the fluorescence intensity of biosensor exposed to object inducers by the basal fluorescence intensity of the biosensor itself.

REFERENCES:
[1] Kaldalu, N., Toots, U., de Lorenzo, V., & Ustav, M. (2000). Functional domains of the TOL plasmid transcription factor XylS. Journal of bacteriology, 182(4), 1118-1126.
[2] Ramos, J. L., Michan, C., Rojo, F., Dwyer, D., & Timmis, K. (1990). Signal-regulator interactions, genetic analysis of the effector binding site of xyls, the benzoate-activated positive regulator of Pseudomonas TOL plasmid meta-cleavage pathway operon. Journal of molecular biology, 211(2), 373-382.
[3] Ramos, J. L., Marqués, S., & Timmis, K. N. (1997). Transcriptional control of the Pseudomonas TOL plasmid catabolic operons is achieved through an interplay of host factors and plasmid-encoded regulators. Annual Reviews in Microbiology, 51(1), 341-373.
[4] Domínguez-Cuevas, P., Marín, P., Busby, S., Ramos, J. L., & Marqués, S. (2008). Roles of effectors in XylS-dependent transcription activation: intramolecular domain derepression and DNA binding. Journal of bacteriology, 190(9), 3118-3128.
[5] Gerischer, U. (2002). Specific and global regulation of genes associated with the degradation of aromatic compounds in bacteria. Journal of molecular microbiology and biotechnology, 4(2), 111-122.
[6] Kaldalu, N., Mandel, T., & Ustav, M. (1996). TOL plasmid transcription factor XylS binds specifically to the Pm operator sequence. Molecular microbiology,20(3), 569-579.
[7] Domínguez-Cuevas, P., Ramos, J. L., & Marqués, S. (2010). Sequential XylS-CTD binding to the Pm promoter induces DNA bending prior to activation. Journal of bacteriology, 192(11), 2682-2690.

Table 1. Comprehensive summary of XylS mutants and accompanied aromatics-sensing characteristics.

Groups Mutations Expected Aromatics-sensing Profiles
Broader aromatics-sensing profiles with high induction ratio Arg45Thr SaA; 4-EtBzO; BzO; 2-MeBzO; 4-MeBzO
Constitutive Pm promoter activation Trp88Leu Not mentioned, this mutant causes constitutive expression of Pm promoter
Broader aromatics-sensing profiles with lower induction ratios Arg152Gly BzO; 2-MeBzO; 2-,3-ClBzO; 2-,3- and 4-MeOBzO
Arg41His BzO; 3-MeBzO; 3-ClBzO; 3-BrBzO; 3-MeOBzO
Asp288Val BzO; 3-MeBzO; 4-MeOBzO; 4-BrBzO; 2,4-MeBzO; 2,5-MeBzO; 3-ClBzO
Leu155Phe 2-MeBzO; 3-MeBzO; 4-MeBzO; 2,5-MeBzO, 4-ClBzO
Pro256Arg BzO; 2-MeBzO; 3-MeBzO; 3,5-MeBzO; 3,5-ClBzO