Team:Cambridge/Experiments/Initial Exercise Group Alpha
From 2011.igem.org
(→Initial Exercise: Joe, Matt, Felix and Gerrit) |
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- | Experiment 1. | + | [['''Experiment 1.''']] |
- | Aim | + | '''Aim''' |
To generate a temporal and or spatial pattern of GFP expression in ''Bacillus subtilis'', using Gibson Assembly to join a sequence of interest to a GFP coding plasmid. | To generate a temporal and or spatial pattern of GFP expression in ''Bacillus subtilis'', using Gibson Assembly to join a sequence of interest to a GFP coding plasmid. | ||
- | Background | + | '''Background''' |
Team Panzer (Gerrit, Joe, Matt and Felix) designed a promoter fusion that linked an SrfA promoter with GFP. SrfA codes for surfactin production, a protein that is produced by ''B. subtilis'' prior to sporulation. SrfA is under the control of ComA, a protein which itself responds to an intercellular population-density-signalling molecule, CSF, in a concentration dependent manner. ComA has low activity at low CSF concentration(low population density), becomes highly active as CSF levels increase, and then less active at higher CSF concentrations. | Team Panzer (Gerrit, Joe, Matt and Felix) designed a promoter fusion that linked an SrfA promoter with GFP. SrfA codes for surfactin production, a protein that is produced by ''B. subtilis'' prior to sporulation. SrfA is under the control of ComA, a protein which itself responds to an intercellular population-density-signalling molecule, CSF, in a concentration dependent manner. ComA has low activity at low CSF concentration(low population density), becomes highly active as CSF levels increase, and then less active at higher CSF concentrations. | ||
Sporulation occurs late in the life cycle of ''B. subtilis'' when the colony reaches a high population density and we hope that GFP could be visualised following overnight growth. If not this paper[http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1178101/?page=2] details some sporulation inducing culture conditions under materials and methods. | Sporulation occurs late in the life cycle of ''B. subtilis'' when the colony reaches a high population density and we hope that GFP could be visualised following overnight growth. If not this paper[http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1178101/?page=2] details some sporulation inducing culture conditions under materials and methods. | ||
- | Predicted results | + | '''Predicted results''' |
- | Bacillus colonies also exhibit a range of colony patterns so we hope that superimposed on the bacillus colony shape will be temporal pattern of green fluorescence indicating which bacteria are on their way to sporulation. | + | Bacillus colonies also exhibit a range of colony patterns so we hope that superimposed on the bacillus colony shape will be |
+ | temporal pattern of green fluorescence indicating which bacteria are on their way to sporulation. | ||
Zero or low GFP detection should be the initial condition, changing to higher GFP activity when SrfA is activated prior to sporulation. This may also mark spatially the regions of the colony where sporulation is about to occur. | Zero or low GFP detection should be the initial condition, changing to higher GFP activity when SrfA is activated prior to sporulation. This may also mark spatially the regions of the colony where sporulation is about to occur. | ||
- | Method | + | |
+ | '''Method''' | ||
We designed 20bp primers with 20bp tails with which to perform gibson assembly to fuse the SrfA promoter with a plasmid containing GFP. | We designed 20bp primers with 20bp tails with which to perform gibson assembly to fuse the SrfA promoter with a plasmid containing GFP. | ||
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- | Technical Data | + | '''Technical Data''' |
We used Finnzymes melting temperature calculator to work out the melting temperature of the primer part (not the tail) of our Gibson Assembly oligos (this was the 3' 20bp of each oligo) these values in degrees C are shown below | We used Finnzymes melting temperature calculator to work out the melting temperature of the primer part (not the tail) of our Gibson Assembly oligos (this was the 3' 20bp of each oligo) these values in degrees C are shown below | ||
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JMF4 - 53.09 | JMF4 - 53.09 | ||
- | Results | + | '''Results''' |
[to be written up] | [to be written up] |
Revision as of 18:09, 7 July 2011
Initial Exercise: Joe, Matt, Felix and Gerrit
Your text etc here. refer to the [http://www.mediawiki.org/wiki/Help:Contents MediaWiki Help] if you are stuck!
Aim To generate a temporal and or spatial pattern of GFP expression in Bacillus subtilis, using Gibson Assembly to join a sequence of interest to a GFP coding plasmid.
Background Team Panzer (Gerrit, Joe, Matt and Felix) designed a promoter fusion that linked an SrfA promoter with GFP. SrfA codes for surfactin production, a protein that is produced by B. subtilis prior to sporulation. SrfA is under the control of ComA, a protein which itself responds to an intercellular population-density-signalling molecule, CSF, in a concentration dependent manner. ComA has low activity at low CSF concentration(low population density), becomes highly active as CSF levels increase, and then less active at higher CSF concentrations.
Sporulation occurs late in the life cycle of B. subtilis when the colony reaches a high population density and we hope that GFP could be visualised following overnight growth. If not this paper[http://www.ncbi.nlm.nih.gov/pmc/articles/PMC1178101/?page=2] details some sporulation inducing culture conditions under materials and methods.
Predicted results
Bacillus colonies also exhibit a range of colony patterns so we hope that superimposed on the bacillus colony shape will be temporal pattern of green fluorescence indicating which bacteria are on their way to sporulation.
Zero or low GFP detection should be the initial condition, changing to higher GFP activity when SrfA is activated prior to sporulation. This may also mark spatially the regions of the colony where sporulation is about to occur.
Method
We designed 20bp primers with 20bp tails with which to perform gibson assembly to fuse the SrfA promoter with a plasmid containing GFP.
The primers arrived as dry pellets with datasheets that detailed the quantity of water required to make these dry pellets into stock solutions of 100uM concentration. We then made a four fold dilution to make 25uM 'working stock' solutions. We were advised to take extra care to make the inital stock amounts perfect as these affect all future dilutions and that making a working stock is useful as it means you have the capacity to repeat your experiment if anything goes awry.
We were provided with genomic DNA from B. subtilis and the vector plasmid containing GFP in two fragments. In addition we were given two primers which would combine with our designed primers to seal the two fragments.
Our three PCR tubes contained: 1. 1ul primer JMF2 1ul primer JMF3 1ul B. subtilis genomic DNA
2. 1ul primer JMF1 1ul primer A Forward (provided) 1ul vector DNA
3. 1ul primer JMF4 1ul primer B reverse (provided) 1ul vector DNA
to each tube we also added: 9.5ul of water 12.5ul Master mix (SyBR Green and Rox, Hotstart Taq polymerase, dNTPs and dyes)
to complete a total volume 25ul total
The complete tubes were run in a real time PCR machine for 30 cycles with a 2 minute extension time and a primer annealing temperature of [INSERT TEMPERATURE HERE]
Technical Data
We used Finnzymes melting temperature calculator to work out the melting temperature of the primer part (not the tail) of our Gibson Assembly oligos (this was the 3' 20bp of each oligo) these values in degrees C are shown below
JMF1 - 56.91 JMF2 - 68.8 JMF3 - 50.48 JMF4 - 53.09
Results [to be written up]