Team:LCG-UNAM-Mexico/Description
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Another important point is that the signal for encapsidation is located in the “cos” sites. It means that you only need this region (about 20 pb, but you increase the efficence of transduction with a region of more that 100 pb) to encapsidate a double DNA strand disregarding the sequence in addition to the cos sites. | Another important point is that the signal for encapsidation is located in the “cos” sites. It means that you only need this region (about 20 pb, but you increase the efficence of transduction with a region of more that 100 pb) to encapsidate a double DNA strand disregarding the sequence in addition to the cos sites. | ||
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*P4 stock production: P2 helper bacteria | *P4 stock production: P2 helper bacteria | ||
Of course after the ligation we don't have viral particles, but naked DNA alone. We thought of a way to overproduce our viral particles without being forced to infect with P2 or getting P2 particles as a byproduct. The solution planned was to construct an E. coli strain containing all the useful genes for P4 in P2 (capsid, tail and lysis operons). In addition to these genes, the helper would also contain the main P2 transactivators (cox and ogr) under a lac operator. This way, after we transform the helper cell with our desired P4 plasmid, we would decide when to promote lysis of the helper bacteria and P4 stock production by adding IPTG. Now we have our biobrick assembled inside ready-to-use phages which can deliver their genome to wildtype bacteria. | Of course after the ligation we don't have viral particles, but naked DNA alone. We thought of a way to overproduce our viral particles without being forced to infect with P2 or getting P2 particles as a byproduct. The solution planned was to construct an E. coli strain containing all the useful genes for P4 in P2 (capsid, tail and lysis operons). In addition to these genes, the helper would also contain the main P2 transactivators (cox and ogr) under a lac operator. This way, after we transform the helper cell with our desired P4 plasmid, we would decide when to promote lysis of the helper bacteria and P4 stock production by adding IPTG. Now we have our biobrick assembled inside ready-to-use phages which can deliver their genome to wildtype bacteria. | ||
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*System delivery: benefits and perspectives. | *System delivery: benefits and perspectives. | ||
- | One of the main motivations for the construction of this delivery system using P4 as the vector is to achieve | + | One of the main motivations for the construction of this delivery system using P4 as the vector is to achieve insertion of devices <br> into cells in an alternative way form traditional transformation. The P4 genome, due to the lack of an Integrase and attachment sites,<br> will stay only as a multicopy plasmid. this reduces the effect of plasmid loss by statistic permanence of at least one copy<br> in each daughter cell. |
This extends the panorama of synthetic biology to the whole P4 host range, which involves especies of genera such as<br> Rhizobium, Klebsiella, and Serratia besides Enterobacteria like E. coli. The delivery of parts into wildtype bacteria<br> could be a pool for innovative applications and properties, such as response specificity in hacking the machinery of<br> a pathogenic bacterium while simply being bypassed in non-hazardous strains; another usage could be to "train" the <br>bacterial population by P4 infection so that it is sensitive to a future stimulus, like indirect activation of <br>medicine producing devices inside bacteria through phage contact. | This extends the panorama of synthetic biology to the whole P4 host range, which involves especies of genera such as<br> Rhizobium, Klebsiella, and Serratia besides Enterobacteria like E. coli. The delivery of parts into wildtype bacteria<br> could be a pool for innovative applications and properties, such as response specificity in hacking the machinery of<br> a pathogenic bacterium while simply being bypassed in non-hazardous strains; another usage could be to "train" the <br>bacterial population by P4 infection so that it is sensitive to a future stimulus, like indirect activation of <br>medicine producing devices inside bacteria through phage contact. |
Revision as of 16:20, 20 October 2009