Team:TUDelft/Conjugation Overview
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='''Module 1: Conjugation system'''= | ='''Module 1: Conjugation system'''= | ||
===Selecting the Conjugation system=== | ===Selecting the Conjugation system=== |
Revision as of 20:06, 12 October 2009
Module 1: Conjugation system
Selecting the Conjugation system
There are many different conjugation systems, with F and IncP being among the most used by previous iGEM teams. The IncP incompatibility group is further divided into two groups IncP-alpha aka Birmingham aka RP4 plasmid and the IncP-beta R751 plasmid. There are several reasons why the IncP system would be better suited for us:
- Smaller plasmid size (R751 is 53423[1]) (RP4 is 60099[2]) (F is 99159[3])
- F has a self-imposed fertility inhibition system (new donors fertile for only about 6 generations), IncP systems have no self-imposed fertility inhibition system[4]
- F has two surface exclusion proteins (TraT, TraS), IncP has only one (trbK)[4]
Selecting genes to knockout
Entry exclusion
The goal of this part of the project is to allow a message plasmid to be transmitted between cells containing conjugation helper plasmids (modified R751). In nature this occurs but at very low levels, due to the presence of entry exclusion proteins[5]. These membrane-bound proteins block incoming transfers from cells containing the conjugative plasmid. Note that in order for the transfer to be blocked their presence is required only in the recipient. These entry exclusion proteins are present for two primary reasons: i) to prevent redundant transfer of the conjugative plasmid among a population of cells and ii) to prevent lethal zygosis[6]. In R751 the gene trbK encodes for the entry exclusion protein in R751 and RP4[7. Its presence is not required for conjugation to occur[8]. Some papers have reported that knocking out the trbK genes in other plasmids did not affect the conjugation frequency: “transfer of the trbK mutant occurred at near-wild-type frequencies”[9]. Given this information we propose to knockout the trbK gene.
Lethal Zygosis
What is lethal zygosis: “We find that diaminopimelic acid in the recipient membrane is released into the medium during bacterial matings, indicating that membrane damage was inflicted on the recipient by the donor, probably for forming a channel for DNA transfer. When the damage is extensive, as in matings with an excess of Hfr bacteria, the F- bacteria are killed (lethal zygosis). The transfer of a large amount of DNA in Hfr matings appears to enhance the killing"[6].
By knocking out the trbK gene we may be exposing our cells to lethal zygosis. If this is indeed the case than knocking out one of the critical mating pair formation genes (trbB, trbC, trbD, trbE, trbF, trbG, trbH, trbI, trbJ, trbL) from the trb operon would prevent this. The gene trbC was selected for this due to its small size and position on the operon. trbC is known to encode for the pilin subunits needed for pilus formation. Given this information we propose to knockout the trbC gene as well.