Team:UCL London/Research/MagnetoSites/Results

From 2011.igem.org

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<h2>Effect of GBS on the level and quality of supercoiling in a plasmid molecule</h2>
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Using fluorescence measurements and shake flask growth we successfully improved the 2009 BBa_K239009 Device by demonstrating how it can function as a better sensor for the stress experienced by E. coli cells harbouring and supercoiling a plasmid that contains a phage GBS. By incorporating a Mu phage GBS , we increases the level of negative supercoiling of the SPY device causing an “easier” expression of GFP in the cells. Thus , we hypothesize that there will be sufficient level of GFP expression even at a very low level of shear stress detected by the SPY device.
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[[File:Ucl-content-Magnetogel3.png|center]]
 
Using fluorescence measurements and shake flask growth we successfully improved the
Using fluorescence measurements and shake flask growth we successfully improved the

Revision as of 04:03, 22 September 2011

Results

Gel photo after PCR cloning of the individual gyrase binding sites

Ucl-content-Magnetogel1.png

The three bands below the 400 bp mark on the gel photo indicate successful PCR of our gyrase binding sites

Chloroquine gel

Ucl-content-Magnetogel555.png

Using chloroquine agarose gel to assay supercoiling, we demonstrated Mu GBS and GBS from pSC101 significantly increase supercoiling of the host plasmid by 42% and 25% respectively. The presence of the pBR322 GBS has significantly altered the level of migration.

As we intended at the design stage, introduction of a mu phage GBS (to make BBa_K676013) has significantly increased supercoiling of the 2009 Device, thus increasing its manufacturability as a commercial pDNA product. The presence of the GBS increased migration (supercoiling) by 10%.


The effect of the presence of a Mu GBS in a plasmid on the stress response

The graph indicates a clear distinction in the level of GFP expression between cell with Spy device and a Mu GBS/Spy device ligation. So this clearly proves that the presence of the Mu bacteriophage gyrase binding site creates a difference in the level of expression of GFP from the plasmid which is conclusive towards an increased stress response.

UclGraph33.png
Ucl-content-Magnetograph.png

Using fluorescence measurements and shake flask growth we successfully improved the 2009 BBa_K239009 Device by demonstrating how it can function as a better sensor for the stress experienced by E. coli cells harbouring and supercoiling a plasmid that contains a phage GBS. By incorporating a Mu phage GBS , we increases the level of negative supercoiling of the SPY device causing an “easier” expression of GFP in the cells. Thus , we hypothesize that there will be sufficient level of GFP expression even at a very low level of shear stress detected by the SPY device.


Using fluorescence measurements and shake flask growth we successfully improved the 2009 BBa_K239009 Device by demonstrating how it can function as a better sensor for the stress experienced by E. coli cells harbouring and supercoiling a plasmid that contains a phage GBS. By incorporating a Mu phage GBS , we increases the level of negative supercoiling of the SPY device causing an “easier” expression of GFP in the cells. Thus , we hypothesize that there will be sufficient level of GFP expression even at a very low level of shear stress detected by the SPY device.