Team:Bonn/Project
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To show one of the many, wide-ranging possible applications, we will fuse a cell death protein, ccdB, to our LOV construct. Upon light exposure, the cell will go into apoptosis. | To show one of the many, wide-ranging possible applications, we will fuse a cell death protein, ccdB, to our LOV construct. Upon light exposure, the cell will go into apoptosis. | ||
- | CcdB is the toxic part of a toxin/antitoxin system on the | + | CcdB is the toxic part of a toxin/antitoxin system on the F plasmid of E.coli. It is coexpressed with its labile antitoxin CcdA, which inhibits the toxic activity by forming a CcdA:CcdB complex. It serves mainly as a plasmid maintenance system: If the plasmid is lost, CcdB is freed due to the rapid degradation of the labile CcdA. It will now attack gyrase, a topoisomerase II, either in its free from or bound to DNA to form a covalent gyrase:DNA adduct, which leads to breakage of double-stranded DNA and plasmid and blockade of polymerases. It eventually results in cell death. |
But CcdA is also able to remove CcdB from its gyrase again as the CcdA:CcdB bond is stronger and therefore rejuvenate the cell. | But CcdA is also able to remove CcdB from its gyrase again as the CcdA:CcdB bond is stronger and therefore rejuvenate the cell. | ||
Revision as of 22:29, 26 September 2012
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Project Summary
Control of protein activity at the peptide level offers spatial-temporal control and quick reaction times, but so far has always involved target-specific tools, such as specific chemical inhibitors or proteases. We are developing and characterizing a fusion construct containing a light sensitive domain that provides quick, universal peptide-level light control of proteins of interest within the framework of easy biobrick-conform coupling.
We are engineering the LOV (Light, Oxygen, Voltage) domain – commonly found in plants where it enables light-directed growth – to control protein activity through blue light. Upon exposure, the LOV domain undergoes a conformational change and shifts away from the protein of interest, uncaging the coupled protein and allowing it to resume activity. In our project, we coupled a small part of the beta-galactosidase (which offers a simple assay) to the LOV domain as a proof-of-principle. We also built a cell death device using ccdB, a gyrase inhibitor. Furthermore we will design a MazF construct, as an example for a Nuclease.
Potential applications of our LOV fusion system include bioreactor regulation or site-specific drug activation.
Project Details
LOV-Blues / Lov-LacZalpha
In our proof-of-principle, we are coupling LacZalpha to the LOV domain. LacZalpha is one of two parts of a split-version beta-galactosidase, which upon exposure to light will resume galactosidase activity in mutants containing LacZomega, the complimentary second part of beta-galactosidase. Using a chromophore substrate for our beta-galactosidase gives us a simple blue-to-white assay.
LOV Kills / LOV-Ccdb
To show one of the many, wide-ranging possible applications, we will fuse a cell death protein, ccdB, to our LOV construct. Upon light exposure, the cell will go into apoptosis.
CcdB is the toxic part of a toxin/antitoxin system on the F plasmid of E.coli. It is coexpressed with its labile antitoxin CcdA, which inhibits the toxic activity by forming a CcdA:CcdB complex. It serves mainly as a plasmid maintenance system: If the plasmid is lost, CcdB is freed due to the rapid degradation of the labile CcdA. It will now attack gyrase, a topoisomerase II, either in its free from or bound to DNA to form a covalent gyrase:DNA adduct, which leads to breakage of double-stranded DNA and plasmid and blockade of polymerases. It eventually results in cell death. But CcdA is also able to remove CcdB from its gyrase again as the CcdA:CcdB bond is stronger and therefore rejuvenate the cell.
LOV Cuts / LOV-MazF
MazF is a ACA-specific ribonuclease from B. subtilis and E. coli which in nature is often used for plasmid-based toxin/antitoxin addiction systems, but also as a kill device in an E. coli programmed death pathway during nutritional stress. It is expressed directly downstream of mazE, its antitoxin, as part of the E. coli chpA operon. Upon suppression of the chpA expression, the quickly deteriorating mazE fails to counterbalance the more stable mazF and cell death ensues. As a consequence we want to use the LOV-MazF fusion construct as a cell death device. The functionality can be verified through a simple assay.
Fusion System
We want to develop a simple Fusion System, which allows anyone a simple coupling of any potential effector to LOV. This system contains a Biobrick compliant LOV domain with the additional restriction site NheI at the C-terminal end for coupling the effector to it. NheI will easily fit with the Biobrick standard, since it is a isocaudomere of XbaI and SpeI. Furthermore the resulting Scar imitates the regular sequence of the Lov Domain leaving no additional Amino-Acids in the fusion construct.
Our Approach
For all the Assays we compare the functionality of a positive-control vector, an inactive sample of the fusion construct with the functionality of the active fusion construct. We obtain the active sample through irradiating with blue light and the inactive sample by leaving the sample in the dark.
LOV-Blues
In order to prove the funtionality of our LOV-LacZalpha construct qualitatively we use a blue/white Assay to monitor the activity of Beta-Galactosidase. This is achieved through adding X-Gal, which is cleaved by the Beta-Galactosidase and so leading to the formation of the chromophore product Indigo.
Constructs provided as Biobricks
pLac-RBS32-LacZalpha-TT-pSB1C3 (control vector)
Additional finished Constructs
pLac-RBS32-LOV-LacZalpha-TT-pSB1C3 (Fusion construct with 2 PstI in the LOV-Domain)
LOV Kills
Constructs provided as Biobricks
pLac-RBS32-Ccdb-TT-pSB1C3 (control vector)
Additional Constructs
pLac-RBS32-LOV-Ccdb-TT-pSB1C3 (Fusion construct with 2 PstI sites in the LOV-Domain)
LOV Cuts
Constructs provided as Biobricks
MazF-pSB1C3
MazF-TT-pSB1C3
For detailed information about the experiments we did in the lab, visit our Notebook.