Team:British Columbia/ProjectChassis

From 2014.igem.org

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We constructed an orthogonal replication system in bacteria that allows the replication of a plasmid, containing the gene of interest, by an error-prone DNA polymerase (DNAP), which does not affect the genomic DNA. To ensure genomic DNA does not get affected, we used two separate plasmids to introduce the error prone replication system. The first plasmid contains a bacterial origin of replication along with T7 bacteriophage replication machinery while the second plasmid contains the gene we are trying to mutagenize or ‘gene of interest’ (GOI) and a viral origin of replication. Other in vivo mutagenesis strategies to evolve genes have been reported. But these techniques do not prevent mutagenesis of genomic DNA in the host or have been applied in other organisms like yeast (3, 4).
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We constructed an orthogonal replication system in bacteria that allows the replication of a plasmid, containing the gene of interest, by an error-prone DNA polymerase (DNAP), which does not affect the genomic DNA. To ensure genomic DNA does not get affected, we used two separate plasmids to introduce the error prone replication system. The first plasmid contains a bacterial origin of replication along with T7 bacteriophage replication machinery while the second plasmid contains the gene we are trying to mutagenize our ‘gene of interest’ (GOI) and a viral origin of replication. Other in vivo mutagenesis strategies to evolve genes have been reported. But these techniques do not prevent mutagenesis of genomic DNA in the host or have been applied in other organisms like yeast (3, 4).
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As a proof of principle we decided to test our system in ''E. coli'' and the same principle can be implemented in other bacteria, like our mineral-binding strain ''Caulobacter''. We utilize the minimal parts of the T7 bacteriophage DNA replication machinery to enable orthogonal replication of a recombinant plasmid. This machinery includes the mentioned DNAP, a primase, a single-stranded DNA-binding protein (ssDNA-BP) and a RNA polymerase (RNAP). After transformation of the recombinant plasmid, containing the viral origin of replication, into the engineered ''E. coli'' strain (Fig. 1A + B) the T7 replication machinery can be induced and the mutation process of the GOI is initiated (Fig. 1C + D). The plasmid containing ''E. coli'' can be cultivated under selective conditions. This allows for simultaneous mutation and selection. For example, in our biomining assay, strains expressing mineral-binding peptides on their surface can be cultivated in the presence of the mineral that is intended to be isolated. Multiple rounds of mutation will eventually lead to peptides that enable efficient selection of the mineral. The mutants that bind best can be isolated in a screen and the plasmid with the mutated GOI can be extracted from the cells (Fig. 1E).  
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As a proof of principle we decided to test our system in <i>E. coli</i> and the same principle can be implemented in other bacteria, like our mineral-binding strain <i>Caulobacter</i>. We utilize the minimal parts of the T7 bacteriophage DNA replication machinery to enable orthogonal replication of a recombinant plasmid. This machinery includes the mentioned DNAP, a primase, a single-stranded DNA-binding protein (ssDNA-BP) and a RNA polymerase (RNAP). After transformation of the recombinant plasmid, containing the viral origin of replication, into the engineered <i>E. coli</i> strain (Fig. 1A + B) the T7 replication machinery can be induced and the mutation process of the GOI is initiated (Fig. 1C + D). The plasmid-containing <i>E. coli</i> can be cultivated under selective conditions. This allows for simultaneous mutation and selection. For example, in our biomining assay, strains expressing mineral-binding peptides on their surface can be cultivated in the presence of the mineral that is intended to be isolated. Multiple rounds of mutation will eventually lead to peptides that enable efficient selection of the mineral. The mutants that bind best can be isolated in a screen and the plasmid with the mutated GOI can be extracted from the cells (Fig. 1E).  
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Our proposed strategy to evolve genes saves the experimenter tremendous amount of time compared to traditional ex vivo methods and is superior to other methods reported for bacteria.
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Our proposed strategy to evolve genes saves the experimenter tremendous amount of time compared to traditional <i>ex vivo</i> methods and is superior to other methods reported for bacteria.
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Latest revision as of 08:11, 26 November 2014

2014 UBC iGEM

© 2014 UBC iGEM