Team:Paris Bettencourt/Designs
From 2011.igem.org
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<p>The following are the experimental designs:</p> | <p>The following are the experimental designs:</p> | ||
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- | <li><a href="https://2011.igem.org/Team:Paris_Bettencourt/GFP_diff">The GFP diffusion experiment:</a> This experiment is the keystone experiment of the paper. One strain expressing GFP is mixed with a wild type strain, and the GFP proteins are diffuses from the GFP+ cells to the wildtype cells.</li> | + | <li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/GFP_diff">The GFP diffusion experiment:</a></em> This experiment is the keystone experiment of the paper. One strain expressing GFP is mixed with a wild type strain, and the GFP proteins are diffuses from the GFP+ cells to the wildtype cells.</li> |
- | <li><a href="https://2011.igem.org/Team:Paris_Bettencourt/GFPLac_diffusion">The YFP-TetR/TetO array experiment:</a> This experiment is an improvement of the previous one. To observe significant fluorescence in the neighboring cell, lots of molecule have to pass through the tubes. Using the affinity of the TetR for the TetO array, we want to concentrate at one point the YFP molecules to better observe this diffusion.</li> | + | <li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/GFPLac_diffusion">The YFP-TetR/TetO array experiment:</a></em> This experiment is an improvement of the previous one. To observe significant fluorescence in the neighboring cell, lots of molecule have to pass through the tubes. Using the affinity of the TetR for the TetO array, we want to concentrate at one point the YFP molecules to better observe this diffusion.</li> |
- | <li><a href="https://2011.igem.org/Team:Paris_Bettencourt/Atb_exp">The antibiotics resistance exchange experiment:</a> This experiment is the most controversial experiment of the paper. The authors claim that a mix of two strains, each of them holding a resistance for a given antibiotic can survive together in a medium containig the two antibiotics because they exchange resistance enzymes through the nanotubes. We found from our experiments that there are other possible explanations for this experiment than the existence of the nanotubes.</li> | + | <li><em><a href="https://2011.igem.org/Team:Paris_Bettencourt/Atb_exp">The antibiotics resistance exchange experiment:</a></em> This experiment is the most controversial experiment of the paper. The authors claim that a mix of two strains, each of them holding a resistance for a given antibiotic can survive together in a medium containig the two antibiotics because they exchange resistance enzymes through the nanotubes. We found from our experiments that there are other possible explanations for this experiment than the existence of the nanotubes.</li> |
</ul> | </ul> | ||
<br> | <br> |
Revision as of 19:35, 20 September 2011
Designs overview
Introduction
Our goal for this summer is characterizing the exchange of proteins through nanotubes as best as we can. We proposed two different expetiments. Firstly, we rely on simple transfer through the nanotubes without having any kind of feedback. We then tried to use signal amplification to enhance our results and give new evidences for a non-specific cell-to-cell communication channel.
We concentrated our effort this summer on the T7 RNA polymerase diffusion, the ComS diffusion and the tRNA amber diffusion.
We had neither direct access to an electronic microscope nor the time to do any electronic microscopy. Our experiments therefore can only support the existence of a non-specific cell-to-cell communication channel which is strongly suspected to be the nanotubes described by Ben-Yehuda.
Simple transfer
In the paper from Dubey and Ben Yehuda, many types of experiments were done to demonstrate the existence and the efficiency of the nanotube network as a means of communication between bacteria. we aimed at reproducing the experiments in Ben Yehuda's paper and to further validate the existence of nanotubes using synthetic biology. This will go a long way to clear the air on the much debated existence of the nanotube method of bacterial cell-cell communication.
We observe directly or indirectly the molecules that have passes through the nanotubes.
The following are the experimental designs:
- The GFP diffusion experiment: This experiment is the keystone experiment of the paper. One strain expressing GFP is mixed with a wild type strain, and the GFP proteins are diffuses from the GFP+ cells to the wildtype cells.
- The YFP-TetR/TetO array experiment: This experiment is an improvement of the previous one. To observe significant fluorescence in the neighboring cell, lots of molecule have to pass through the tubes. Using the affinity of the TetR for the TetO array, we want to concentrate at one point the YFP molecules to better observe this diffusion.
- The antibiotics resistance exchange experiment: This experiment is the most controversial experiment of the paper. The authors claim that a mix of two strains, each of them holding a resistance for a given antibiotic can survive together in a medium containig the two antibiotics because they exchange resistance enzymes through the nanotubes. We found from our experiments that there are other possible explanations for this experiment than the existence of the nanotubes.
Designs for nanotube characterization
Key specification of our designs
The aim of our project is to characterize and try to control the cellular communication through the nanotubes by using the techniques of synthetic biology. The idea was to build artificial systems to explore more deeply the properties of cells.
The first question about nanotubes we ask is what kind of molecules can pass through the nanotubes? Thus the size range of the molecules that can pass.The paper shows that GFP, calcein and plasmids can pass, but what if the molecule passing is bigger?
We then wondered at the transfer process in the tube. Is it simple diffusion or an active process?
We started designing the project with these two questions in mind. Using several molecules of very different sizes, from a T7 polymerase to a tRNA amber supressor, we aim to test the capability and size limit for the molecules that can pass through the tubes. But, if the diffusion is passive, the speed of diffusion should be proportional to the diffusion coefficient D, that is to say invertially proportinal to the radius of the object. Can we design a fast-responding system that would allow us to measure this time?
We decided that our constructs should follow the global idea summed up in the following picture:The problem is that each design needs a different couple of signal emittor/receptor. However, even with good modelling, the response time cannot be predicted easily because much is not known about the transfer through the nanotubes. We tried to mitigate the impact of this issue by the following measures:
- Each time the same actuator and the same monitor was used to have comparable response times in different systems.
- The relevant measure is not response time itself but the increase of response time between the same strains (where all of the construct emitter and receptor is in one strain) and the emitter strain/receptor in different strains.
Designs of testing B. Subtilis to B. Subtilis communication
In B.subtilis, nanotubes are reported to be formed by the cytoplasms. We had to find a molecule that can be expressed in the first cell that can trigger a genetic circuit in the second cell. The image below illustrates the idea:
As discussed earlier, the goal is to pass several types of molecules, with different sizes, and see if we can observe an increase in the response time with the size of the molecule. The molecules chosen cover 3 order of magnitude of size. They are classified from the biggest to the smallest. The major systems which received much attention during the summer are:
- T7 polymerase diffusion: The T7 RNA polymerase is the RNA polymerase of the T7 phage. This is a big molecule, that recognizes a very specific promoter orthogonal to B.subtilis.
- KinA diffusion: The idea is to make a complex partner to diffuse from one cell to the other in order to trigger the sporulation of the second cell, even in exponential phase.
- ComS diffusion: ComS is an inhibitor of the MecA protease in B.subtilis. It plays a key role in the triggering of the competence and sporulation mechanisms. The idea is to trigger the switch of the MeKS system of the receptor cell by diffusing ComS through the nanotubes. A major precaution is to prevent the first cell from sporulating.
- Amber suppressor tRNA diffusion: The principle of this design is to produce in one cell a amber supressor tRNA that will diffuse through the nanotubes. The receptor cell holds the gene for T7 with amber stop codons that cannot be translated into a functional protein as long as the tRNA amber suppressor is not present in the cell. Once expressed, the functional amber T7 RNA polymerase will trigger the T7 amplification system.
Inter-species communication
The article demonstrates that nanotubes established inside the B.subtilis family can also be formed between B.subtilis and an E.coli. These two types of bacteria are really different since one is Gram+ and the other is Gram-. Their membrane is really different since there is no periplasm in B.subtilis. The existence of inter-species nanotubes did really spiked our interest and we also created designs to test this aspect of the nanotube communication.
B.subtilis is Gram- so the nanotubes seem to create a link from the cytoplasm of the first cell to the cytoplasm of the second cell. In the case of the Gram+ bacteria, like E.coli, we wonder which membrane forms the nanotubes . Do they create a link with the periplasm, or with the cytoplasm? To test the two hypotheses, we tried to create a design for each of the two possibilities. If one work and the other does not, the answer to this question will be known.
Designs for B. Subtilis-E. Coli communication
If nanotube communication can be established between E.coli and B.subtilis, it is not known whether the communication happens through the cytoplasm or the periplasm. To test these two hypotheses, two designs were made:
If communication happens with the cytoplasm
The image below sums up the kind of connection that can be established if nanotubes connect the two cytoplasms. Hence, some of the designs we have shown above are still available for B.subtilis to E.coli.
Here are the designs tested in this case. Our major systems, those we investigated most during the summer are in bold.
- T7 polymerase diffusion: The T7 RNA polymerase is the RNA polymerase of the T7 phage. This is a pretty big molecule, that recognizes a very specific promoter orthogonal to B.subtilis and E.coli.
- C1(ind) diffusion: Thanks to our collaboration with the Pekin iGEM Team, we had the possibility to reuse the push-on push-off system they designed last year (2010). We want to diffuse from B.subtilis the molecule C1 that will trigger a change in the toggle switch state in E.coli.
- Xis protein diffusion: Xis is a small partner of an excisase. The latter will excise a stop codon on the DNA strand that is preventing the expression of the GFP.We had no time to build this design, but the idea is summed up on the linked page.
- Amber suppressor tRNA diffusion: The principle of this design is to produce in one cell an amber supressor tRNA that will diffuse through the nanotubes. The receptor cell holds the gene for a T7 with amber stop codons that cannot be translated into a functional protein as long as the tRNA amber suppressor is not present in the cell. Once expressed, the functional amber T7 RNA polymerase will trigger the T7 amplification system.
If communication happens with the periplasm
In case the communication happens with the periplasm, we have to think about molecules that can be then transported into the cytoplasm.
We had to design more sophisticated approaches. The ideas are the following:
- MBP diffusion: we need a CRP+, MBP- E.coli mutant. We produce the MBP protein in B.subtilis and make it diffuse through the nanotubes. As long as the MBP has not reached the periplasm of E.coli, the cell cannot digest the maltose in the medium. The indirect induction of MalR by MBP triggers the expression of the GFP reporter.
- OmpR diffusion: we need a OmpR- Receptor* E.coli mutant. We produce the OmpR protein in B.subtilis. As long as the OmpR has not diffused from B.subtilis, the signaling cascade cannot be activated. With the rescue by B.subtilis of the OmpR protein, the expression of the reporter gene is activated.
Can we conclude on these design?
If one of these designs works, it will be proved that the inter-species nanotube communication exists and this will eventually show location of the connection with the membrane. There was limited time to test these designs but we propose these designs for future iGEM teams to investigate.