Team:DTU-Denmark-2/results/data page

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<b></b>Plug ‘n’ Play biobricks<br>
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<b>Plug 'n' Play Assembly Standard and BioBricks</b><br> <br>
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We think that iGEM should be about combining biobricks in any thinkable way fast and easy, leaving more time for characterization of parts and focusing on the actual project. Therefore we have developed a novel assembly standard called Plug'n'Play with DNA based on uracil excision based cloning. The concept of our assembly standard is that iGEM teams receive a kit containing ready to use PCR products of every single biobrick. This allow for the teams to select the biobricks they need mix them in a USER reaction incubate it and 70 min later, competent E. coli cells can be transformed. The use of preproduced PCR products may be to unconventional for some people and therefore the kit also contains what we call a back-up plasmid containing all parts in the kit, so if you use up all your PCR product or you prefer to run our own PCR you simply use the back-up plasmids. 
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We have constructed more than 48 biobricks containing the standardized overhangs that facilitates the DNA ligase free cloning and 34 unique vectors.<br><br>
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We believe that the restriction-enzyme based assembly methods have too many drawbacks for creating advanced synthetic biology - especially in higher eukaryotes as mammals and fungi. Therefore, we have developed a novel assembly standard called Plug 'n' Play  with DNA based on uracil-specific excision reagent cloning. The Plug 'n' Play assembly standard allows construction and customization of multi-part devices fast and easy.<br><br>
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In combination with our new assembly standard, we introduce a novel approach for the principal of BioBricks.
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Our vision is that each iGEM team receives a kit containing ready to use PCR products of every single BioBrick. These BioBricks are ready for assembly by just performing a USER enzyme reaction and subsequently a traditional <i>E. coli</i> transformation. Hereby, the cumbersome process with restriction enzymes and ligases is avoided. This further allows time to be spent on creating innovative ideas within synthetic biology, leaving more time for characterization of BioBricks and creating innovative Genetically Engineered Machines.
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The Plug 'n' Play  with DNA kit contains pre-produced PCR products and back-up plasmids for each part in the kit.
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So far the Plug 'n' Play  with DNA kit contains 50 BioBricks and 21 plasmids for mammalian cells and <i>Aspergilli</i>.
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The method applies long complementary overhangs on the PCR product(s) as well as the destination vector. These overhangs can anneal each other to form a stable hybridization product. The overhangs on the PCR product are custom made and independent of restriction sites, which is very convenient when working with fungi and mammalian cells.All the parts in the form of PCR-products will be distributed in microtiter plates directly ready for cloning.
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The ease and fastness of Plug ’n’ Play with DNA has been demonstrated by developing a fluorescent reporter system for both Aspergillus nidulans and mammalian cells.
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The Technology
 
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The technology is based on the Uracil-Specific Excision Reagent (USER) that is an enzyme that generates a single nucleotide gap at the location of a uracil. Biobricks and vectors are constructed by designing primers for PCR that contain a uracil with additional nucleotides at the 5’ ends.  and following the PCR products can directly be treated with USER™ Enzyme, resulting in unique 3´ single-stranded extensions. These unique extensions allow the correct annealing to the vector. The extensions on both biobricks and vector have been designed in such a way that the single-stranded extensions not are complementary, thereby the vector will not anneal with itself and furthermore ensures the correct orientation and placement of the inserted biobricks. The result of the USER cloning is a vector and biobricks assembled into the desired molecule, directly ready for transformation of chemically competent E. coli cells.
 
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<b>How it works</b>
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PCR products are first mixed together with USER enzyme. The USER enzyme generates a single nucleotide gap at the location of the uracil in the PCR product thereby generating a 8-9 bp long complementary overhang. These overhangs can anneal each other to form a stable hybridization product. The nicks in the assembled plasmid are repaired by <i>E. coli</i>.<br>
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As proof of concept of our assembly standard, we designed a reporter system for <i>Aspergillus nidulans</i> and mammalian cells. The figure shows an example of this where the mammalian cell line U-2 OS is transfected with a Plug ‘n’ Play assembled plasmid expressing GFP with a targeting sequence localizing the produced GFP to the peroxisomes of the cell. As a proof of concept of the Plug ‘n’ Play assembly system, the Copenhagen team proved the easy assembly as well as successful function in bacteria.
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<b>Data For Our Favorite Parts </b> <br/>
<b>Data For Our Favorite Parts </b> <br/>
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1.<a href="http://partsregistry.org/Part:BBa_K678000">Main page</a> - <b>DMKP-P6 promoter, BBa_K678000,</b> The specific activity of the constitutive promoter was assayed and compared to a strong promoter the promoter appears to be of medium strength.<br/>
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1. <a href="http://partsregistry.org/Part:BBa_K678000">Main page</a> - <b>DMKP-P6 promoter, BBa_K678000,</b> The specific activity of the constitutive promoter was assayed and compared to a known strong promoter. The DMKP-P6 promoter appears to be of medium strength.<br/>
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2.<a href="http://partsregistry.org/Part:BBa_K678001">Main page</a> - <b>PalcA promoter, BBa_K678001 </b>. .<br/>
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2. <a href="http://partsregistry.org/Part:BBa_K678001">Main page</a> - <b>PalcA promoter, BBa_K678001, </b> The specific activity of the inducible promoter was assayed and compared to a known strong promoter. The promoter appears to be of medium strength .<br/>
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3.<a href="http://partsregistry.org/Part:BBa_K678002">Main page</a> - <b>Device for expression of GFP in mammalian cells, BBa_K678002,</b> This device was used to transfect the mammalian cell line U-2 OS and as expected resulted in the localization of GFP to the peroxisomes.
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3. <a href="http://partsregistry.org/Part:BBa_K678002">Main page</a> - <b>Device for expression of GFP in mammalian cells, BBa_K678002,</b> This device was used to transfect the mammalian cell line U-2 OS and as expected resulted in the localization of GFP to the peroxisomes.
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<b>Data For Pre-existing parts </b> <br/>
<b>Data For Pre-existing parts </b> <br/>
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1.<a href="http://partsregistry.org/Part:BBa_J52034:Experience">Experience</a> - <b>CMV promoter, BBa_J52034 </b><br/>
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1. <a href="http://partsregistry.org/Part:BBa_J52034:Experience">Experience</a> - <b>CMV promoter, BBa_J52034, </b>This promoter was used as the regulator for our reporter system for mammalian cells. We tested the suitability of the CMV promoter for the expression of enhanced GFP, YFP, CFP, and mCherry as well enhanced GFP targeted to the peroxisomes. The promoter worked well as a strong constitutive promoter.<br/>
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<b>We've also characterized the following parts </b> <br/>
<b>We've also characterized the following parts </b> <br/>
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1.<a href="http://partsregistry.org/Part:BBa_">Main page</a> - <b>BBa_K678XXX </b><br/>
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1. <a href="http://partsregistry.org/Part:BBa_K678049">Main page</a> - <b>pJEJAM1, BBa_K678049, </b>Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of enhanced GFP in the cell.<br/>
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2. <a href="http://partsregistry.org/Part:BBa_K678050">Main page</a> - <b>pJEJAM2, BBa_K678050,</b>Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in the localization of enhanced GFP to the peroxisomes of the cell.<br/>
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3. <a href="http://partsregistry.org/Part:BBa_K678051">Main page</a> - <b>pJEJAM3, BBa_K678051,</b>Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of YFP in the cell.<br/>
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4. <a href="http://partsregistry.org/Part:BBa_K678052">Main page</a> - <b>pJEJAM4, BBa_K678052, </b>Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of mCherry in the cell.<br/>
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5. <a href="http://partsregistry.org/Part:BBa_K678053">Main page</a> - <b>pJEJAM5, BBa_K678053, </b>Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of CFP in the cell.<br/>
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6. <a href="http://partsregistry.org/Part:BBa_K678060">Main page</a> - <b>pJEJAM12, BBa_K678060, </b>Plasmid intended for genomic integration in <i>A. nidulans</i>. Expression of this plasmid results in a homogeneous distribution of GFP.<br/>
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7. <a href="http://partsregistry.org/Part:BBa_K678061">Main page</a> - <b>pJEJAM13, BBa_K678061, </b>Plasmid intended for genomic integration in <i>A. nidulans</i>. Expression of this plasmid results in the localization of GFP to the peroxisomes.<br/>
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8. <a href="http://partsregistry.org/Part:BBa_K678062">Main page</a> - <b>pJEJAM14, BBa_K678062, </b>Plasmid intended for genomic integration in <i>A. nidulans</i>. Expression of this plasmid results in a homogeneous distribution mRFP<br/>
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9. <a href="http://partsregistry.org/Part:BBa_K678063">Main page</a> - <b>pJEJAM15, BBa_K678063, </b>Plasmid intended for genomic integration in <i>A. nidulans</i>. Expression of this plasmid results in the localization of mRFP to the nucleus.<br/>
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10. <a href="http://partsregistry.org/Part:BBa_K678070">Main page</a> - <b>p68, BBa_K678070, </b>This plasmid was used to qualitatively and quantitatively analyse the promoters DMKP-P6 and PalcA in <i>A. nidulans</i><br/>
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Latest revision as of 21:29, 21 September 2011





Plug 'n' Play Assembly Standard and BioBricks

We believe that the restriction-enzyme based assembly methods have too many drawbacks for creating advanced synthetic biology - especially in higher eukaryotes as mammals and fungi. Therefore, we have developed a novel assembly standard called Plug 'n' Play with DNA based on uracil-specific excision reagent cloning. The Plug 'n' Play assembly standard allows construction and customization of multi-part devices fast and easy.

In combination with our new assembly standard, we introduce a novel approach for the principal of BioBricks. Our vision is that each iGEM team receives a kit containing ready to use PCR products of every single BioBrick. These BioBricks are ready for assembly by just performing a USER enzyme reaction and subsequently a traditional E. coli transformation. Hereby, the cumbersome process with restriction enzymes and ligases is avoided. This further allows time to be spent on creating innovative ideas within synthetic biology, leaving more time for characterization of BioBricks and creating innovative Genetically Engineered Machines.

The Plug 'n' Play with DNA kit contains pre-produced PCR products and back-up plasmids for each part in the kit. So far the Plug 'n' Play with DNA kit contains 50 BioBricks and 21 plasmids for mammalian cells and Aspergilli.



How it works



PCR products are first mixed together with USER enzyme. The USER enzyme generates a single nucleotide gap at the location of the uracil in the PCR product thereby generating a 8-9 bp long complementary overhang. These overhangs can anneal each other to form a stable hybridization product. The nicks in the assembled plasmid are repaired by E. coli.

As proof of concept of our assembly standard, we designed a reporter system for Aspergillus nidulans and mammalian cells. The figure shows an example of this where the mammalian cell line U-2 OS is transfected with a Plug ‘n’ Play assembled plasmid expressing GFP with a targeting sequence localizing the produced GFP to the peroxisomes of the cell. As a proof of concept of the Plug ‘n’ Play assembly system, the Copenhagen team proved the easy assembly as well as successful function in bacteria.

Data For Our Favorite Parts
1. Main page - DMKP-P6 promoter, BBa_K678000, The specific activity of the constitutive promoter was assayed and compared to a known strong promoter. The DMKP-P6 promoter appears to be of medium strength.
2. Main page - PalcA promoter, BBa_K678001, The specific activity of the inducible promoter was assayed and compared to a known strong promoter. The promoter appears to be of medium strength .
3. Main page - Device for expression of GFP in mammalian cells, BBa_K678002, This device was used to transfect the mammalian cell line U-2 OS and as expected resulted in the localization of GFP to the peroxisomes.


Data For Pre-existing parts
1. Experience - CMV promoter, BBa_J52034, This promoter was used as the regulator for our reporter system for mammalian cells. We tested the suitability of the CMV promoter for the expression of enhanced GFP, YFP, CFP, and mCherry as well enhanced GFP targeted to the peroxisomes. The promoter worked well as a strong constitutive promoter.


We've also characterized the following parts
1. Main page - pJEJAM1, BBa_K678049, Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of enhanced GFP in the cell.
2. Main page - pJEJAM2, BBa_K678050,Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in the localization of enhanced GFP to the peroxisomes of the cell.
3. Main page - pJEJAM3, BBa_K678051,Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of YFP in the cell.
4. Main page - pJEJAM4, BBa_K678052, Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of mCherry in the cell.
5. Main page - pJEJAM5, BBa_K678053, Plasmid for transient transfection of mammalian cells. Expression of this plasmid results in a homogeneous distribution of CFP in the cell.
6. Main page - pJEJAM12, BBa_K678060, Plasmid intended for genomic integration in A. nidulans. Expression of this plasmid results in a homogeneous distribution of GFP.
7. Main page - pJEJAM13, BBa_K678061, Plasmid intended for genomic integration in A. nidulans. Expression of this plasmid results in the localization of GFP to the peroxisomes.
8. Main page - pJEJAM14, BBa_K678062, Plasmid intended for genomic integration in A. nidulans. Expression of this plasmid results in a homogeneous distribution mRFP
9. Main page - pJEJAM15, BBa_K678063, Plasmid intended for genomic integration in A. nidulans. Expression of this plasmid results in the localization of mRFP to the nucleus.
10. Main page - p68, BBa_K678070, This plasmid was used to qualitatively and quantitatively analyse the promoters DMKP-P6 and PalcA in A. nidulans