Team:Tsinghua-E/Part1

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  A plasmid  used for the construction of high-diversity library in vivo ingenome level. In  this vector, highly error-prone <em>dnaQ</em> mutant, <em>mutD</em><a href="#_ENREF_1" title="Lou, 2012 #499">1</a> was cloned downstream  of <em>araBAD</em> promoter to control the  mutation rate of the target genome by the concentration of <em>araBAD</em> promoter’s inducer, L-arabinose, in a strict manner.<em>E. Coli</em> JM109 carrying different vectors  of pBAD_B0030-<em>mutD</em>-<em>sfGFP</em>, pBAD_B0032-<em>mutD</em>-<em>sfGFP</em> and pBAD_SDA_RBS-<em>mutD-sfGFP</em>(this RBS sequence was derived  from the RBS sequence upstream of sfGFP in original AraC_pBAD_CI_OR222-sfGFP  vector<a href="#_ENREF_2" title="Lou, 2012 #499">2</a>)were  constructed. By detecting the induced fluorescence intensity, we found that pBAD_B0030-<em>mutD</em>-<em>sfGFP</em>,  andpBAD_SDA_RBS-<em>mutD- sfGFP</em>have  relatively higher <em>mutD</em> expression. The increaseof mutation rate induced  by our mutation part was measured by quantifying the reversion of rifampinresistance  caused by mutation in genome.pBAD_SDA_RBS-<em>mutD-  sfGFP</em>could increase the genome mutation rate up to 10 times compared with  negative control with 1g/L induction concentration of L-arabinose. <br />
  A plasmid  used for the construction of high-diversity library in vivo ingenome level. In  this vector, highly error-prone <em>dnaQ</em> mutant, <em>mutD</em><a href="#_ENREF_1" title="Lou, 2012 #499">1</a> was cloned downstream  of <em>araBAD</em> promoter to control the  mutation rate of the target genome by the concentration of <em>araBAD</em> promoter’s inducer, L-arabinose, in a strict manner.<em>E. Coli</em> JM109 carrying different vectors  of pBAD_B0030-<em>mutD</em>-<em>sfGFP</em>, pBAD_B0032-<em>mutD</em>-<em>sfGFP</em> and pBAD_SDA_RBS-<em>mutD-sfGFP</em>(this RBS sequence was derived  from the RBS sequence upstream of sfGFP in original AraC_pBAD_CI_OR222-sfGFP  vector<a href="#_ENREF_2" title="Lou, 2012 #499">2</a>)were  constructed. By detecting the induced fluorescence intensity, we found that pBAD_B0030-<em>mutD</em>-<em>sfGFP</em>,  andpBAD_SDA_RBS-<em>mutD- sfGFP</em>have  relatively higher <em>mutD</em> expression. The increaseof mutation rate induced  by our mutation part was measured by quantifying the reversion of rifampinresistance  caused by mutation in genome.pBAD_SDA_RBS-<em>mutD-  sfGFP</em>could increase the genome mutation rate up to 10 times compared with  negative control with 1g/L induction concentration of L-arabinose. <br />
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Revision as of 15:44, 23 September 2013

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Part 1: THU-E Mutation Part

Mut.jpg
A plasmid  used for the construction of high-diversity library in vivo ingenome level. In  this vector, highly error-prone dnaQ mutant, mutD<a href="#_ENREF_1" title="Lou, 2012 #499">1</a> was cloned downstream  of araBAD promoter to control the  mutation rate of the target genome by the concentration of araBAD promoter’s inducer, L-arabinose, in a strict manner.E. Coli JM109 carrying different vectors  of pBAD_B0030-mutD-sfGFP, pBAD_B0032-mutD-sfGFP and pBAD_SDA_RBS-mutD-sfGFP(this RBS sequence was derived  from the RBS sequence upstream of sfGFP in original AraC_pBAD_CI_OR222-sfGFP  vector<a href="#_ENREF_2" title="Lou, 2012 #499">2</a>)were  constructed. By detecting the induced fluorescence intensity, we found that pBAD_B0030-mutD-sfGFP,  andpBAD_SDA_RBS-mutD- sfGFPhave  relatively higher mutD expression. The increaseof mutation rate induced  by our mutation part was measured by quantifying the reversion of rifampinresistance  caused by mutation in genome.pBAD_SDA_RBS-mutD-  sfGFPcould increase the genome mutation rate up to 10 times compared with  negative control with 1g/L induction concentration of L-arabinose. 



Figure.2 rifampicin reversion mutants caused by mutD expression and the counts by agar plate

Figure.3 Conception illustration of the working mechanism of mutD


1 Schaaper, R. M. MECHANISMS OF MUTAGENESIS IN THE ESCHERICHIA-COLI MUTATOR MUTD5 - ROLE OF DNA MISMATCH REPAIR. Proc. Natl. Acad. Sci. U. S. A. 85, 8126-8130,doi:10.1073/pnas.85.21.8126 (1988).
2 Lou, C. B., Stanton, B., Chen, Y. J., Munsky, B. & Voigt, C. A. Ribozyme-based insulator parts buffer synthetic circuits from genetic context. Nature Biotechnology 30, 1137-+, doi:10.1038/nbt.2401 (2012).