Team:ULB-Brussels/Project/WetLab
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<p>Alkaline phosphatase (phoA) is a periplasmic enzyme whose activity is easily detectable, even at low level, on chromogenic substrate (XP-medium (5-bromo-4-chloro-3-indolyl phosphate)). It is usually used to study protein secretion, but we will use it as a molecular marker for the activity of the 2A peptide. If phoA is correctly synthetized and exported in the periplasm, the substrate acquires a characteristic blue color. (Hoffman and Wright 1985; van Geest and Lolkema 2000) | <p>Alkaline phosphatase (phoA) is a periplasmic enzyme whose activity is easily detectable, even at low level, on chromogenic substrate (XP-medium (5-bromo-4-chloro-3-indolyl phosphate)). It is usually used to study protein secretion, but we will use it as a molecular marker for the activity of the 2A peptide. If phoA is correctly synthetized and exported in the periplasm, the substrate acquires a characteristic blue color. (Hoffman and Wright 1985; van Geest and Lolkema 2000) | ||
In order to assess the efficacity of the 2A peptid, we need to design a plasmid containing 2 molecular markers (the red fluorescent protein (RFP) and phoA separated by a 2A peptide (RFP::2A::phoA). After cloning this plasmid in bacteria lacking the phoA gene in their genome (those bacteria were obtained from E.coli Keio Knockout collection) and after growth on chromogenic and selective XP-medium, we should be able to observe 4 types of results:</p> | In order to assess the efficacity of the 2A peptid, we need to design a plasmid containing 2 molecular markers (the red fluorescent protein (RFP) and phoA separated by a 2A peptide (RFP::2A::phoA). After cloning this plasmid in bacteria lacking the phoA gene in their genome (those bacteria were obtained from E.coli Keio Knockout collection) and after growth on chromogenic and selective XP-medium, we should be able to observe 4 types of results:</p> | ||
- | 1. Colourless colonies and medium </p> | + | 1. Colourless colonies and blue medium </p> |
- | 2. | + | 2. Colourless colonies and colourless medium</p> |
- | 3. | + | 3. Red colonies and blue medium</p> |
- | 4. Red colonies and | + | 4. Red colonies and colourless medium.</p> |
- | <p> | + | <p>The only interesting case is the third because the PI is functional and the rapporteur protein is active. However, some controls must be made.</p> |
- | <p>Two control groups will be needed for this experiment.</p> | + | <p>Two different control groups will be needed for this experiment.</p> |
- | The first control will be colonies expressing the construction RFP::phoA, which should confirm that | + | The first control will be colonies expressing the construction RFP::phoA, which should confirm that phoA are not active when 2A is not functional. Therefore, we can observe blue medium only when there is cleavage of the peptide 2A.</p> |
The second control is actually a control experiment, which will be done by insertion of proline::phoA sequences into bacteria lacking the phoA gene, and growth on chromogenic and selective XP-medium. </p> | The second control is actually a control experiment, which will be done by insertion of proline::phoA sequences into bacteria lacking the phoA gene, and growth on chromogenic and selective XP-medium. </p> | ||
<p>Indeed, the N-terminal extremity of phoA is a signal sequence that allows it to be translocated into the bacterial periplasm, where it will be folded in its active form. (Hoffman and Wright 1985; van Geest and Lolkema 2000) It means that the addition of the prolin from the 2A peptide to the N-extremity of phoA (Luke, 2012) could possibly disrupt the translocation process. If such a phenomenon should occur, our positive screening would reveal only negative results for phoA, even when the 2A peptide works correctly. We must thus design this control experiment in order to check that the translocation of phoA in the periplasm occurs even if we add a prolin on its N-extremity. | <p>Indeed, the N-terminal extremity of phoA is a signal sequence that allows it to be translocated into the bacterial periplasm, where it will be folded in its active form. (Hoffman and Wright 1985; van Geest and Lolkema 2000) It means that the addition of the prolin from the 2A peptide to the N-extremity of phoA (Luke, 2012) could possibly disrupt the translocation process. If such a phenomenon should occur, our positive screening would reveal only negative results for phoA, even when the 2A peptide works correctly. We must thus design this control experiment in order to check that the translocation of phoA in the periplasm occurs even if we add a prolin on its N-extremity. | ||
The control experiment should produce one of the following results:</p> | The control experiment should produce one of the following results:</p> | ||
- | - Colonies | + | - Colonies on blue medium</p> |
- Colonies on colourless medium.</p> | - Colonies on colourless medium.</p> | ||
<p>If proline::phoA bacteria colour their medium, it will mean that the alkaline phosphatase can be translocated into the periplasm even if it is fused with an additional proline on its N-extremity. The previous experiment (Screening of different phoA-like sequences) will thus be carried on. If their medium remains colourless, it means that we cannot use phoA to test the activity of the 2A peptides and we will have to re-design an experiment with other molecular markers. The control group of this control experiment will consist of bacteria lacking the phoA gene in which we will have inserted the phoA gene ourselves, and it should produce bacteria that colour their XP-medium.</p> | <p>If proline::phoA bacteria colour their medium, it will mean that the alkaline phosphatase can be translocated into the periplasm even if it is fused with an additional proline on its N-extremity. The previous experiment (Screening of different phoA-like sequences) will thus be carried on. If their medium remains colourless, it means that we cannot use phoA to test the activity of the 2A peptides and we will have to re-design an experiment with other molecular markers. The control group of this control experiment will consist of bacteria lacking the phoA gene in which we will have inserted the phoA gene ourselves, and it should produce bacteria that colour their XP-medium.</p> |
Revision as of 15:36, 10 October 2014
$~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ \newcommand{\MyColi}{{\small Mighty\hspace{0.12cm}Coli}} \newcommand{\Stabi}{\small Stabi}$ $\newcommand{\EColi}{\small E.coli} \newcommand{\SCere}{\small S.cerevisae}\\[0cm] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ \newcommand{\PI}{\small PI}$ $\newcommand{\Igo}{\Large\mathcal{I}} \newcommand{\Tgo}{\Large\mathcal{T}} \newcommand{\Ogo}{\Large\mathcal{O}} ~$
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