Team:ETH Zurich/Wetlab/Overview
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We decided to build a simple pulse generator based on LacI IS mutants, which upon expression rapidly silence lac-controlled expression despite presence of IPTG. This allows us to induce expression with IPTG and terminate expression by addition of tetracyline. Since it is independent of removal of inducer by complete exchange of medium, it can be used inside the chemostat.<br><br> | We decided to build a simple pulse generator based on LacI IS mutants, which upon expression rapidly silence lac-controlled expression despite presence of IPTG. This allows us to induce expression with IPTG and terminate expression by addition of tetracyline. Since it is independent of removal of inducer by complete exchange of medium, it can be used inside the chemostat.<br><br> | ||
'''Results:''' <br> | '''Results:''' <br> | ||
- | Using PCR-based site-directed mutagenesis we generated eight different mutants of LacI and characterized them in a simple genetic experiment. As it turned out, all of them repressed lac-controlled expression even at high concentrations of IPTG. We constructed a pulse generator consisting of a tet-controlled LacI IS generator and a constitutive TetR expression cassette and demonstrated that leaky expression of the protein of interest as well as repression of lac-controlled expression due to leaky expression of LacI IS are not problematic | + | Using PCR-based site-directed mutagenesis we generated eight different mutants of LacI and characterized them in a simple genetic experiment. As it turned out, all of them repressed lac-controlled expression even at high concentrations of IPTG. We constructed a pulse generator consisting of a tet-controlled LacI IS generator and a constitutive TetR expression cassette and demonstrated that leaky expression of the protein of interest as well as repression of lac-controlled expression due to leaky expression of LacI IS are not problematic. <br><br> |
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Latest revision as of 03:34, 30 October 2008
OverviewIn order to approach our goal of creating an E. coli strain carrying a minimal genome, there are three main problems that have to be overcome:
Chemostat selection: introduce a limitation that confers a growth advantage to organisms with smaller genomes Switch circuit: design a biobrick that provides for short-term synthesis of the desired gene products
Genome ReductionTo prove that in vivo restriction and religation is possible is fundamental to our project which relies on short-term expression of a restriction enzyme and a ligase. While the restriction enzyme will randomly cut DNA, the simultaneous or shortly delayed synthesis of the ligase should religate the DNA. If the DNA is cut at several sites, religation will lead to exclusion of chromosomal fragments in a random manner. Chemostat selectionIn the continuous culture of a chemostat, those organisms with the highest rate of proliferation will overgrow those with a smaller growth rate. In order to bypass the need of selecting for those E. coli which have successfully reduced their genomes by massive screening of thousands of clones, we need to introduce a constraint that confers a growth advantage to organisms with smaller genomes. We have chosen to introduce mutations in the nucleotide synthesis pathway to achieve this goal. This will render DNA replication the rate-limiting step of proliferation and therefore be advantageous to organisms with small genomes. Switch circuitExpression of restriction enzymes that cut genomic DNA inside the cell is likely to decrease viability. Actually, the Waterloo iGEM team is using restriction enzymes to kill cells in their project this year. Therefore, construction of a switch circuit, which allows to restrict expression of the restriction enzyme to a short period of time, is a crucial part of the project. The switch circuit allows expression of a gene under control of the lac repressor and rapid termination of lac-controlled expression despite presence of inducer by expression of an engineered LacI mutant, which is unresponsive to IPTG.
Outline
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