Difference between revisions of "Part:BBa K1602006"

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         <h1>Inducible itaconic acid producing operon (only cadA)</h1>
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         <h1>Inducible itaconic acid producing construct (only cadA)</h1>
 
         <b>Itaconic acid</b> is an organic, dicarboxylic acid that is biotechnologically synthesized most commonly in Aspergillus terreus. It is derived          from citric acid via 2 intermediates and a final decarboxylation.
 
         <b>Itaconic acid</b> is an organic, dicarboxylic acid that is biotechnologically synthesized most commonly in Aspergillus terreus. It is derived          from citric acid via 2 intermediates and a final decarboxylation.
 
         <br>
 
         <br>
         To enable this pathway in <i>Escherichia coli</i> it is necessary to introduce 1 genes. This gene is taken from the genome <i>Apergillus terreus</i>. It is coding for a cis-aconitate decarboxylase (cadA). An Enzyme that catalyzes the following chemical reaction:
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         To enable this pathway in <i>Escherichia coli</i> it is necessary to introduce 1 genes. This gene is taken from the genome of <i>Apergillus terreus</i>. It is coding for a cis-aconitate decarboxylase (cadA). An Enzyme that catalyzes the following chemical reaction:
        <br>
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         <img style="width: 900px; height: 110px; margin-left: 15px; margin-right: 15px;" alt="" src="pictures/chem_way.jpg">
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        <div align="center">
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         <img style="width: 682px; height: 120px; margin-left: 15px; margin-right: 15px;" alt="" src="https://static.igem.org/mediawiki/2015/c/ce/Synthese_cadA_v2.png">
 
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<img style="width: 900px; height: 110px; margin-left: 15px; margin-right: 15px;" alt="" src=" https://static.igem.org/mediawiki/2015/a/ae/Itaconic_acid_chemistry.jpg">
 
<img style="width: 900px; height: 110px; margin-left: 15px; margin-right: 15px;" alt="" src=" https://static.igem.org/mediawiki/2015/a/ae/Itaconic_acid_chemistry.jpg">
 
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         <p align="left" style="width: 900px; margin-left: 15px; margin-right: 15px;" alt="">
             <b>Figure 1</b> Reaction scheme of the itaconic acid producing operon (only cadA). The substrate for the reaction are cis-aconitate. Cis-aconitate is metabolized to itaconic acid in 1 step by decarboxylation.
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             <b>Figure 1</b> Reaction scheme of the itaconic acid producing operon (only cadA). The substrate for the reaction is cis-aconitate. Cis-aconitate is metabolized to itaconic acid in 1 step by decarboxylation.
 
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      ===<h2>Usage</h2>===
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===<h2>Usage</h2>===
 
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             This part is a composite of one coding genes, provided with a strong RBS (<a href="/Part:BBa_B0034">BBa_B0034</a>) and under control of a T7 Promoter (<a href="/Part:BBa_I719005">BBa_I719005</a>).
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             This part is a composite of one coding gene, provided with a strong RBS (<a href="/Part:BBa_B0034">BBa_B0034</a>) and under control of a T7 Promoter (<a href="/Part:BBa_I719005">BBa_I719005</a>). Optimization of this operon may be possible through introduction of 2 more genes. Namely gltA <a href="/Part:BBa_K1602001">(citrate synthase)</a> and acnA (Aconitase).
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                    <div style="float: right;"><img style="width: 400px; height: 120px;" alt="" src="pictures/gene_operon.png"> </div>  
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                    <img style="width: 332px; height: 200px;" alt="" src="https://static.igem.org/mediawiki/2015/0/05/T7_cadA_scheme_operon.png">
 
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<div style="float: right;"><img style="width: 400px; height: 120px;" alt="" src="http://2015.igem.org/File:T7_cadA_scheme_operon.png"> </div>  
https://static.igem.org/mediawiki/2015/a/a1/Itaconic_acid_gene_operon.png"> </div>  
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===<h2>Results</h2>===
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The expression of cadA has been visualized via SDS-PAGE. Positive clones were grown at 37&deg; celsius until an OD of 0,7. Afterwards the cells were induced utilizing 20&micro;l of 1M IPTG for 12h at 28&deg; celsius. Finally the cells were lysated via ultrasonic cell disruption.
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    <table>
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            <td align= "center" valign="middle">
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                <div><img style="width: 200px; height: 389px;" src="https://static.igem.org/mediawiki/2015/3/35/Da15_sds_cadA.png" href="https://static.igem.org/mediawiki/2015/3/35/Da15_sds_cadA.png"></div>
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            </td>
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            <td align= "center" valign="middle">
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                <div><img style="width: 300px; height: 456;" src="https://static.igem.org/mediawiki/2015/a/a7/Da15_sds_cadA_plot.png" href="https://static.igem.org/mediawiki/2015/a/a7/Da15_sds_cadA_plot.png"</div>
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            <td align="left">
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                <div><b>Figure 3</b> Scan of the PAGE containing from left to right a marker (M; Protein Marker III AppliChem), the positive sample (1) and a negative control (2). The picture was cropped and edited for clarification purposes.</div>
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            </td>
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            <td align="left">
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                <div><b>Figure 4</b> Plot of the gel lanes based on contrast analyses - created with ImageJ</div>
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        </colgroup>
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    </table>
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    <div>
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<br>
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<h3>cadA Assay</h3>
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The decarboxylic activity of cadA was shown via a pH indicator assay. As a byproduct of the catalytic conversion of cis-aconitate to itaconic acid carbon dioxide is released into the assay mixture. Here it forms carbonic acid and thereby lowers the pH value of the mixture. This is visualized through the indicator bromothymol blue (BTB) which changes its configuration state depending on the surrounding pH-Value (pH 6.0 - 7.6). That change of configuration can be shown via a photometric analysis in a TECAN® Infinite 200 PRO microplate reader. The resulting data sheets are then put into a plotting script written in R and exported as a ggplot.
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<br>
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<br>
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The assay was performed as following:<br>
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First Na<sub>2</sub>HPO<sub>4</sub> was adjusted to a pH of 7.0 to function as a buffer. The final concentration of Na<sub>2</sub>HPO<sub>4</sub> was 5mM. The assay system contained 10% (v/v) indicator stock (BTB) and 20 ul were added per well. As a negative control a purified TES protein fraction from disrupted BL21 cells was used. In a range from 0mM to 1mM (0,2mM steps; total of 6 reactions) cis-aconitate (substrate), dissolved in Na<sub>2</sub>HPO<sub>4</sub>-buffer solution was added per well to enable the enzymatic conversion. To put the turnover into relation with the maximum turnover we added extra rows that contained equal amounts of substrate and product (itaconic acid). Finally a row containing just itaconic acid was put at the bottom to be able to use the resulting values as a blank for the assay. All samples were prepared on ice.
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<br><br>
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The 96 well microplate was loaded as depicted in the picture below:
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<a href="https://static.igem.org/mediawiki/2015/thumb/0/08/Da15_cadA_plate_assay.png/800px-Da15_cadA_plate_assay.png">
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<img src="https://static.igem.org/mediawiki/2015/thumb/0/08/Da15_cadA_plate_assay.png/320px-Da15_cadA_plate_assay.png">
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</a>
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The assay was run for 200 kinetic cycles, each 30 secs long and with 25 photo pulses per cycle. The reader was heated to the appropriate temperature of 37&deg; celsius. Absorbance was measured at the absorption maximum of BTB which in this case is 620nm.
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  </td>
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<b>Figure 5</b> 96-well microplate layout
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</td>
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<td valign="middle">
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<b>Figure 6</b> The plot on the right hand side is showing the change in absorption of the bromothymol blue in solution for the three different kinds of samples in correlation to the kinetic cycles i.e time.
 +
<ul>
 +
<li>The 'p' curve shows the absolute conversion of educt to product (product curve).</li>
 +
<li>The 'ca' curve shows the enzymatic activity of cadA. The activity explains the steady rise of the curve which comes from the acidification of the assay mixture in those wells. Because of the conversion from cis-aconitate to itaconic acid and the byproduct carbon dioxide (which forms bicarbonate acid) and lowers the pH</li>
 +
<li>The 'k' curve shows the negative control containing TES protein fraction without cadA.</li>
 +
</ul>
 +
The sudden drop of the 'p' curve in the beginning of the measurement could be explained through various reasons. One could be that the bubbles that formed in the wells when adding the chemicals could interfere with the light. Also the different substances were added on ice so when the plate was put in the heated reader water in the air might have condensated at the bottom of the wells and hinder the light beam. The resulting vibrations of shutting doors too harshly might also interfere with the plate moving mechanism inside the reader and cause malfunctioning.
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</td>
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<td valign="middle" align="center">
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<img src="https://static.igem.org/mediawiki/2015/thumb/c/c0/Da15_e2_blank_cadA.png/700px-Da15_e2_blank_cadA.png" width="466px" height="400px" href="https://static.igem.org/mediawiki/2015/c/c0/Da15_e2_blank_cadA.png">
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</table>
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 +
<a href="http://2015.igem.org/Team:TU_Darmstadt/Project/Bio/Monomeres/Results#HPLC">Link to our through HPLC achieved results</a>
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    </div>
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    <p>The code utilized to render the plots is embedded below.</p>
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<iframe src="http://pastebin.com/embed_iframe.php?i=9xmJJWgr" style="border:none;width:100%;height:300px"></iframe>
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    </body>
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===<h2>Sequence and Features</h2>===
 
===<h2>Sequence and Features</h2>===
 
<partinfo>BBA_K1602006 SequenceAndFeatures</partinfo>
 
<partinfo>BBA_K1602006 SequenceAndFeatures</partinfo>

Latest revision as of 22:29, 20 September 2015

Inducible itaconic acid producing construct (only cadA)

Itaconic acid is an organic, dicarboxylic acid that is biotechnologically synthesized most commonly in Aspergillus terreus. It is derived from citric acid via 2 intermediates and a final decarboxylation.
To enable this pathway in Escherichia coli it is necessary to introduce 1 genes. This gene is taken from the genome of Apergillus terreus. It is coding for a cis-aconitate decarboxylase (cadA). An Enzyme that catalyzes the following chemical reaction:

Figure 1 Reaction scheme of the itaconic acid producing operon (only cadA). The substrate for the reaction is cis-aconitate. Cis-aconitate is metabolized to itaconic acid in 1 step by decarboxylation.



Usage

This part is a composite of one coding gene, provided with a strong RBS (BBa_B0034) and under control of a T7 Promoter (BBa_I719005). Optimization of this operon may be possible through introduction of 2 more genes. Namely gltA (citrate synthase) and acnA (Aconitase).


Figure 2 Genetic map of the itaconic acid producing operon (only cadA) with T7 promoter. This brick enables E.Coli BL21 cells to synthesize itaconic acid in presence of the inductor IPTG.


Results

The expression of cadA has been visualized via SDS-PAGE. Positive clones were grown at 37° celsius until an OD of 0,7. Afterwards the cells were induced utilizing 20µl of 1M IPTG for 12h at 28° celsius. Finally the cells were lysated via ultrasonic cell disruption.

Figure 3 Scan of the PAGE containing from left to right a marker (M; Protein Marker III AppliChem), the positive sample (1) and a negative control (2). The picture was cropped and edited for clarification purposes.
Figure 4 Plot of the gel lanes based on contrast analyses - created with ImageJ



cadA Assay

The decarboxylic activity of cadA was shown via a pH indicator assay. As a byproduct of the catalytic conversion of cis-aconitate to itaconic acid carbon dioxide is released into the assay mixture. Here it forms carbonic acid and thereby lowers the pH value of the mixture. This is visualized through the indicator bromothymol blue (BTB) which changes its configuration state depending on the surrounding pH-Value (pH 6.0 - 7.6). That change of configuration can be shown via a photometric analysis in a TECAN® Infinite 200 PRO microplate reader. The resulting data sheets are then put into a plotting script written in R and exported as a ggplot.

The assay was performed as following:
First Na2HPO4 was adjusted to a pH of 7.0 to function as a buffer. The final concentration of Na2HPO4 was 5mM. The assay system contained 10% (v/v) indicator stock (BTB) and 20 ul were added per well. As a negative control a purified TES protein fraction from disrupted BL21 cells was used. In a range from 0mM to 1mM (0,2mM steps; total of 6 reactions) cis-aconitate (substrate), dissolved in Na2HPO4-buffer solution was added per well to enable the enzymatic conversion. To put the turnover into relation with the maximum turnover we added extra rows that contained equal amounts of substrate and product (itaconic acid). Finally a row containing just itaconic acid was put at the bottom to be able to use the resulting values as a blank for the assay. All samples were prepared on ice.

The 96 well microplate was loaded as depicted in the picture below:

The assay was run for 200 kinetic cycles, each 30 secs long and with 25 photo pulses per cycle. The reader was heated to the appropriate temperature of 37° celsius. Absorbance was measured at the absorption maximum of BTB which in this case is 620nm.
Figure 5 96-well microplate layout
Figure 6 The plot on the right hand side is showing the change in absorption of the bromothymol blue in solution for the three different kinds of samples in correlation to the kinetic cycles i.e time.
  • The 'p' curve shows the absolute conversion of educt to product (product curve).
  • The 'ca' curve shows the enzymatic activity of cadA. The activity explains the steady rise of the curve which comes from the acidification of the assay mixture in those wells. Because of the conversion from cis-aconitate to itaconic acid and the byproduct carbon dioxide (which forms bicarbonate acid) and lowers the pH
  • The 'k' curve shows the negative control containing TES protein fraction without cadA.
The sudden drop of the 'p' curve in the beginning of the measurement could be explained through various reasons. One could be that the bubbles that formed in the wells when adding the chemicals could interfere with the light. Also the different substances were added on ice so when the plate was put in the heated reader water in the air might have condensated at the bottom of the wells and hinder the light beam. The resulting vibrations of shutting doors too harshly might also interfere with the plate moving mechanism inside the reader and cause malfunctioning.
Link to our through HPLC achieved results

The code utilized to render the plots is embedded below.

Sequence and Features


Assembly Compatibility:
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    COMPATIBLE WITH RFC[1000]