Team:DTU Denmark/USERprinciple

From 2009.igem.org

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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark" >Home</a></font> </td>
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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark/team" >The Team</a> </font></td>
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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark/project" >The Project</a> </font></td>
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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark/parts" >Parts submitted</a> </font></td>
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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark/modelling">Modelling</a></font> </td>
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    <td align="center" ><font face="arial" size="3"><a class="mainLinks" href="https://2009.igem.org/Team:DTU_Denmark/notebook" title="Day to day lab activity">Notebook</a>
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  <br>
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  The redoxilator<br><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/genetic_design" CLASS=leftbar>- Genetic design</a><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/applications" CLASS=leftbar>- Applications and perspectives</a><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/results" CLASS=leftbar>- Results</a><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/safety" CLASS=leftbar>- Safety considerations</a><br><br>
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    <br>The USER assembly standard<br><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/USERprinciple" CLASS=leftbar>- USER fusion of biobricks</a><br><br>
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  <font color="#990000" face="arial" size="3">
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    <br>USER fusion primer design software<br><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/USERprogram" CLASS=leftbar>- Abstract</a><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/USERprograminstructions" CLASS=leftbar>- Instructions</a><br>
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    <a href="https://2009.igem.org/Team:DTU_Denmark/USERprogramoutputformat" CLASS=leftbar>- Output format</a><br>
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  <br>
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  <b>The project</b><br><br><br>
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<!-- INSERT MAIN TEXT HERE! (formatting: <b>bold</> <i>italic> <h4>header</h4>) -->
<p>
<p>
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The USER fusion assembly standard allows rapid construction of multi-part devices, without some of the drawbacks of the restriction-enzyme based standard biobrick assembly method. The full USER<sup>TM</sup> assembly standard can be found here: (<a href="http://openwetware.org/wiki/The_BioBricks_Foundation:RFC#BBF_RFC_39:_The_USER_cloning_standard" target="_blank">BBF RFC 39</a>). The main advantages of this assembly method is:<br>
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The USER fusion assembly standard allows rapid construction of multi-part devices, without some of the drawbacks of the restriction-enzyme based standard biobrick assembly method. The full USER assembly standard can be found here: (<a href="http://openwetware.org/wiki/The_BioBricks_Foundation:RFC#BBF_RFC_39:_The_USER_cloning_standard" target="_blank">BBF RFC 39</a>). The main advantages of this assembly method is:<br>
<br>
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  1) The USER fusion biobrick plasmid is digested with the restriction enzyme pacI and the nicking enzyme Nt.BbvCI (a nicking enzyme cuts only one strand as illustrated on the figure). This process will linearize the plasmid, and make single stranded overhangs (sticky ends).<br>
  1) The USER fusion biobrick plasmid is digested with the restriction enzyme pacI and the nicking enzyme Nt.BbvCI (a nicking enzyme cuts only one strand as illustrated on the figure). This process will linearize the plasmid, and make single stranded overhangs (sticky ends).<br>
  2) PCR amplification is performed on the biobricks intended for the fusion. The primer design is facilitated by our novel USER fusion primer design software made for this iGEM project.<br>
  2) PCR amplification is performed on the biobricks intended for the fusion. The primer design is facilitated by our novel USER fusion primer design software made for this iGEM project.<br>
-
  3) USER<sup>TM</sup> enzyme mix is added. This will remove the uracil always included in the primers, making sticky end overhangs on all biobricks. Because of the matching sticky ends on all biobricks and linearized plamid, the biobricks will self-assemble in the plasmid.<br>
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  3) USER enzyme mix is added. This will remove the uracil always included in the primers, making sticky end overhangs on all biobricks. Because of the matching sticky ends on all biobricks and linearized plamid, the biobricks will self-assemble in the plasmid.<br>
  Two or more biobricks have been joined with all the advantages mentioned above.<br><br>
  Two or more biobricks have been joined with all the advantages mentioned above.<br><br>
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<a href="http://igem.grafiki.org/" CLASS=leftbar target="blank">Design your primers here</a><br><br>
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<b>Design your primers with PHUSER <a href="http://igem.grafiki.org/" CLASS=leftbar target="blank">here</a></b><br><br>
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  <b>Synthetic Biology</b><br><br>
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<!-- INSERT GREY BOX TEXT HERE! (formatting: <b>bold</> <i>italic> <h4>header</h4>) -->
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<p align="left"><i>“Synthetic Biology is an art of engineering new biological systems that don’t exist in nature.”</i><br></p>
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<p align="right"><i>-Paras Chopra & Akhil Kamma</i><br><br></p>
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<p>In nature, biological molecules work together in complex systems to serve purposes of the cell. In synthetic biology these molecules are used as individual functional units that are combined to form tailored systems exhibiting complex dynamical behaviour. From ‘design specifications’ generated from computational modelling, engineering-based approaches enables the construction of such new specified gene-regulatory networks. The ultimate goal of synthetic biology is to construct systems that gain new functions, and the perspectives of the technology are enormous. It has already been used in several medical projects2 and is predicted to play a major role in biotech-production and environmental aspects.</p>
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Comments or questions to the team? Please <a href="mailto:igem@bio.dtu.dk" CLASS=email>Email us</a> -- Comments of questions to webmaster? Please <a href="mailto:lronn@bio.dtu.dk" CLASS=email>Email us</a>
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Revision as of 21:27, 20 October 2009

Wiki banner 967px.png

The project


The redoxilator

- Genetic design
- Applications and perspectives
- Results
- Safety considerations


The USER assembly standard

- USER fusion of biobricks


USER fusion primer design software

- Abstract
- Instructions
- Output format

The project


The USER fusion assembly standard allows rapid construction of multi-part devices, without some of the drawbacks of the restriction-enzyme based standard biobrick assembly method. The full USER assembly standard can be found here: (BBF RFC 39). The main advantages of this assembly method is:

1. Standardized method for assembling several BioBricks or components at a time, in contrast to the one at a time" assembly procedure normally used.
2. Since the method relies PCR based assembly, all restriction sites are allowed in the biobricks.
3. Eight basepair-overhangs allows ligase-free cloning. With the enclosed protocol E. coli can be transformed with a multipart-construct less than 2 hours after your PCR-reaction has completed.
4. The biobricks are joined without leaving a scar which is ideal for fusing protein domain biobricks.
5. Insertions of small sequences between biobricks such as a intracellular localization signal, restriction site or flexible linker is possible with the right primer design.
6. High fidelity is ensured by using PfuTurbo® Cx Hotstart DNA polymerase.
7. By the design of the PCR tails, it can be decided whether the USER cassette should be deleted, copied or moved following insertion.
8. Directionality of inserts are supported.


USER fusion of biobricks - how it works
We have successfully constructed a USER fusion biobrick (BBa_K194003), and demonstrated that it works as expected. The biobrick includes a DNA-sequence needed for USER-fusion, which consists of a restriction site and two nicking sites. The entire process of fusing two biobricks are illustrated in the figure, and the same can be done for multiple fragments at once.

principle of USER fusion


Procedure (please refer to our Biobrick Assembly Standard BBF RFC 39 for a detailed protocol):

1) The USER fusion biobrick plasmid is digested with the restriction enzyme pacI and the nicking enzyme Nt.BbvCI (a nicking enzyme cuts only one strand as illustrated on the figure). This process will linearize the plasmid, and make single stranded overhangs (sticky ends).
2) PCR amplification is performed on the biobricks intended for the fusion. The primer design is facilitated by our novel USER fusion primer design software made for this iGEM project.
3) USER enzyme mix is added. This will remove the uracil always included in the primers, making sticky end overhangs on all biobricks. Because of the matching sticky ends on all biobricks and linearized plamid, the biobricks will self-assemble in the plasmid.
Two or more biobricks have been joined with all the advantages mentioned above.

Design your primers with PHUSER here

Synthetic Biology

“Synthetic Biology is an art of engineering new biological systems that don’t exist in nature.”

-Paras Chopra & Akhil Kamma

In nature, biological molecules work together in complex systems to serve purposes of the cell. In synthetic biology these molecules are used as individual functional units that are combined to form tailored systems exhibiting complex dynamical behaviour. From ‘design specifications’ generated from computational modelling, engineering-based approaches enables the construction of such new specified gene-regulatory networks. The ultimate goal of synthetic biology is to construct systems that gain new functions, and the perspectives of the technology are enormous. It has already been used in several medical projects2 and is predicted to play a major role in biotech-production and environmental aspects.

Comments or questions to the team? Please -- Comments of questions to webmaster? Please