Team:Gdansk-UG/Project

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                 <td width="116" align="center" valign="middle"><p><a href="https://2013.igem.org/Team:Gdansk-UG/Parts">Parts Submitted</a></p>
                 <td width="116" align="center" valign="middle"><p><a href="https://2013.igem.org/Team:Gdansk-UG/Parts">Parts Submitted</a></p>
                   <a href="https://2013.igem.org/Team:Gdansk-UG/Parts">                  to the Registry</a></td>
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                                <td width="99" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Notebook">Notebook</a></td>
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                <td width="86" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Modeling">Human Practice</a></td>
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                <td width="99" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Notebook">Notebook</a></td>
                 <td width="68" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Safety">Safety</a></td>
                 <td width="68" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Safety">Safety</a></td>
                 <td width="82" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Attributions">Attributions</a></td>
                 <td width="82" align="center" valign="middle"><a href="https://2013.igem.org/Team:Gdansk-UG/Attributions">Attributions</a></td>
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                             <td width="50%" align="left" valign="top"><h2>Welcome to our Site</h2></td>
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                             <td width="50%" align="left" valign="top"><h2>Our project plan</h2></td>
                             <td width="50%" align="left" valign="top">&nbsp;</td>
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                        <td align="left" valign="top"><p>We are a group of students from Poland, Gda&#324;sk and we are better at biotechnology than at html.</p></td>
 
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                        <td align="left" valign="top">&nbsp;</td>
 
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                           <td width="739" align="left" valign="top"><p>&nbsp;</p>
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                           <td width="739" align="left" valign="top"><p>We are aiming to construct a bacterium which  would be able detect methanol in ethanol solutions.<br />
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                            The reason for choosing this subject is the  constant problem of people consuming alcohol which has methanol levels  exceeding permissible limits. As we all know, methanol it a very toxic  compound. Its consumption may lead to damaging nervous system and even death.  Therefore, a test that would enable people to check ethanol alcohol purity  would prevent a whole lot of cases of people hospitalized because of methanol  intoxication. <br />
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                             <p>We aim to construct bacteria able to detect methanol in ethanol solutions. Our project focuses on using a methanol-dependent promoter and a gene regulated by it &ndash; methanol dehydrogenase. We would like to introduce bacteria, which &ndash;in presence of methanol &ndash; would produce a dye, for instance, GFP. <br />
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                            The aim of our project is to have not only  a reliable test, but also easy to perform, without usage of specialized lab  equipment. The idea is that a normal, average person could check with our test  the level of dangerous compound at home. </p>
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<p>&nbsp;</p>
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                             <p>&nbsp;<strong>Step I.</strong></p>
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                              Firstly, we wanted to design a BioBrick  consisting of our methanol &ndash; dependent promoter. It is the core of our project,  so we decided to mainly focus on it.&nbsp; In  theory the plan that we prepared was clear and easy &ndash; but, of course, nothing  is predictable in lab J The part itself fortunately didn&rsquo;t include any restriction sites  that we would have to get rid of, so the only thing that we had to do was  isolating genomic DNA from <em>M.organophilum</em>,  PCR with primers matching our promoter sequence and ligation of the PCR product  with plasmid Backbone.&nbsp; </p>
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                              <strong>Step II.</strong></p>
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                              The second step that we planned to do was to check if our BioBrick is properly working. The bacterium on which we wanted to test it was <em>E.coli</em> TOP10 F&rsquo; strain. We decided that the reporter protein which we will use is GFP and catechol oxidase. </p>
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                              <strong>Step III.</strong></p>
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                              After checking, if the BioBrick which we  constructed is working, we wanted to ligate our part with pKT230 plasmid. The  aim of this procedure was to create a plasmid that would be maintained by <em>Zymomonas mobilis</em>. After a thorough  research we decided, that <em>Zymomonas mobilis</em>, although it&rsquo;s hard to transform, would be a best host to our  plasmid due to its high resistance to ethanol.&nbsp; </p>
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                               <strong>Step IV. </strong></p>
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                              The last step was to measure the efficiency  of reporter protein production by <em>Zymomonas  mobilis</em> in different concentrations of methanol.</p>
                             <p>&nbsp;</p>
                             <p>&nbsp;</p>
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                             <p>The main problem is to find a promoter that  is insensible to ethanol. Unfortunately, the most suitable organism &ndash; <em>Picha pastoris</em> &ndash; has methanol-dependent  promoters which are blocked in the presence of ethanol. Therefore, we have  found a bacterium which is an obligate methylotroph &ndash; <em>Methylobacillus flagellatus</em>. It is unable to utilize 2-carbon  compounds due to the absence of enzymes present in TCA cycle. Based on that  fact we speculate that the inhibition of the promoter will not take place.<br />
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                             <p><strong>Results. </strong></p>
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                              We would like to present two different  approaches to our project. Depending on initial results, we will take different  measures to reaching our goal. Being restricted by the possibility that the  promoter may not act as we would like it to, we thought of another route. </p>
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                               Unfortunately, due to lack of time, we  couldn&rsquo;t execute our whole project plan. What we achieved, was creation of the methanol-dependent promoter BioBrick. We didn&rsquo;t have time to measure how well it&rsquo;s working. We also constructed pKT230 plasmid with an insert consisting of  methanol-dependent promoter and GFP. We hope to continue or work after the  Jamboree. Next step ahead of us: <em>Z.mobilis</em> transformation!</p>
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                              The first method, based on methanol-dependent promoter is very clear and easy to achieve. Provided that  this promoter is insensible to ethanol and that it works well in our final,  transformed organism, we only have to measure the efficiency of dye production in different concentrations of alcohols. <br />
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                            <p>&nbsp;</p></td>
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                              The other approach focuses on the reaction catalyzed by methanol dehydrogenase. This enzyme, in the presence of NAD+, is able to alter methanol into formaldehyde. <br />
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                              While detecting the methanol with simple  measures is very hard, performing a colorimetric reaction with formaldehyde seems  to be quite possible. We are hoping that the enzyme shows higher affinity to  methanol than to ethanol, but even if it doesn&rsquo;t &ndash; this method would still be sufficiently  precise to detect low concentrations of one-carbon alcohol.<br />
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                            Taking into account that we may decide to  follow the second route, we are also gathering information about detecting  formaldehyde in purely biological ways. We found a formaldehyde operon but,  unfortunately, there is not enough information about it.&nbsp; We are hoping to find either an enzyme,  promoter or an operon that would enable us to insert into bacteria a sequence  resulting in producing colored substance during bacterial growth in methanol. </p></td>
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Latest revision as of 16:28, 3 October 2013

Gdansk UG

Home Team

Official

Team Profile

Project

Parts Submitted

to the Registry
Human Practice Notebook Safety Attributions

Our project plan

 

We are aiming to construct a bacterium which would be able detect methanol in ethanol solutions.
The reason for choosing this subject is the constant problem of people consuming alcohol which has methanol levels exceeding permissible limits. As we all know, methanol it a very toxic compound. Its consumption may lead to damaging nervous system and even death. Therefore, a test that would enable people to check ethanol alcohol purity would prevent a whole lot of cases of people hospitalized because of methanol intoxication.
The aim of our project is to have not only a reliable test, but also easy to perform, without usage of specialized lab equipment. The idea is that a normal, average person could check with our test the level of dangerous compound at home.

 

 Step I.


Firstly, we wanted to design a BioBrick consisting of our methanol – dependent promoter. It is the core of our project, so we decided to mainly focus on it.  In theory the plan that we prepared was clear and easy – but, of course, nothing is predictable in lab J The part itself fortunately didn’t include any restriction sites that we would have to get rid of, so the only thing that we had to do was isolating genomic DNA from M.organophilum, PCR with primers matching our promoter sequence and ligation of the PCR product with plasmid Backbone. 


Step II.


The second step that we planned to do was to check if our BioBrick is properly working. The bacterium on which we wanted to test it was E.coli TOP10 F’ strain. We decided that the reporter protein which we will use is GFP and catechol oxidase.


Step III.


After checking, if the BioBrick which we constructed is working, we wanted to ligate our part with pKT230 plasmid. The aim of this procedure was to create a plasmid that would be maintained by Zymomonas mobilis. After a thorough research we decided, that Zymomonas mobilis, although it’s hard to transform, would be a best host to our plasmid due to its high resistance to ethanol. 


Step IV.


The last step was to measure the efficiency of reporter protein production by Zymomonas mobilis in different concentrations of methanol.

 

Results.


Unfortunately, due to lack of time, we couldn’t execute our whole project plan. What we achieved, was creation of the methanol-dependent promoter BioBrick. We didn’t have time to measure how well it’s working. We also constructed pKT230 plasmid with an insert consisting of methanol-dependent promoter and GFP. We hope to continue or work after the Jamboree. Next step ahead of us: Z.mobilis transformation!