Difference between revisions of "Part:BBa K2923018:Experience"
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===Introduction=== | ===Introduction=== | ||
− | To validate the designed constructs we decided to test | + | To validate the designed constructs we decided to test Theophylline switch-off (stop auto-cleavage in presence of ligand). For negative control, we choose an inactive form of aptazyme: mutation at the ribozyme domain. iGEM Strasbourg designed construct requires the use of aptazyme linked to MS2 and PP7 stem-loops. The following results described MS2-MS2-Aptazyme-PP7-PP7 activity in in-vitro and in-vivo assays. |
===In-vitro assay of BBa_K2923018=== | ===In-vitro assay of BBa_K2923018=== | ||
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Before to start an in vivo experiment on aptazymes, we characterized the constructs created by Berry KE and Hochschild as positive and negative controls. | Before to start an in vivo experiment on aptazymes, we characterized the constructs created by Berry KE and Hochschild as positive and negative controls. | ||
− | A ß-galactosidase activity positive control also called BH3 corresponds to <partinfo>BBa_K2923000</partinfo>. A ß-galactosidase activity negative control, called BH2 correspond to empty plasmid backbone. | + | A ß-galactosidase activity positive control also called BH3 corresponds to <partinfo>BBa_K2923000</partinfo>. A ß-galactosidase activity negative control, called BH2 correspond to an empty plasmid backbone. |
− | Theophylline aptazyme is switch-off (self-cleaves in absence of ligand) and prevents ß-galactosidase transcription. It was | + | Theophylline aptazyme is switch-off (self-cleaves in absence of ligand) and prevents ß-galactosidase transcription. It was analyzed in the presence of its inactive form and BH2, BH3 controls (Figure 2). |
[[Image: Aptazyme Theo 0.jpg|300px|thumb|center| Figure 2: ß-galactosidase assay on Theophylline aptazyme in absence of ligand]] | [[Image: Aptazyme Theo 0.jpg|300px|thumb|center| Figure 2: ß-galactosidase assay on Theophylline aptazyme in absence of ligand]] | ||
− | Theophylline aptazyme has | + | Theophylline aptazyme has a ß-galactosidase activity profile similar to BH2 and BH3 controls, which promotes its use as a ligand sensor in the designed three-hybrid system. This data confirms that aptazymes could be compatible with three-hybrid systems. |
===In-vivo: ß-galactosidase assay in the presence of ligand=== | ===In-vivo: ß-galactosidase assay in the presence of ligand=== | ||
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[[Image: Aptazyme Theo 2,5.jpg|300px|thumb|center| Figure 3. ß-galactosidase assay on Theophylline aptazyme in presence of Theophylline (2,5 mM)]] | [[Image: Aptazyme Theo 2,5.jpg|300px|thumb|center| Figure 3. ß-galactosidase assay on Theophylline aptazyme in presence of Theophylline (2,5 mM)]] | ||
− | We obtained the expected results for all controls, | + | We obtained the expected results for all controls, but theophylline ligand did not have effects on the three-bacterial hybrid system. Despite that, the active form of theophylline aptazyme is not sensitive to its ligand. Any significant ß-galactosidase activity increase was observed in the presence of Theophylline ligand compared to an inactive control. |
− | To increase the chances to obtain positives results for Theophylline aptazyme we choose to | + | To increase the chances to obtain positives results for Theophylline aptazyme we choose to perform the same experiment with a higher concentration of Theophylline ligand (5mM) (Figure 4). |
[[Image: Aptazyme Theo 5.jpg|300px|thumb|center| Figure 4. ß-galactosidase assay on Theophylline aptazyme in presence of Theophylline (5 mM)]] | [[Image: Aptazyme Theo 5.jpg|300px|thumb|center| Figure 4. ß-galactosidase assay on Theophylline aptazyme in presence of Theophylline (5 mM)]] | ||
− | However, the obtained results | + | However, the obtained results show that Theophylline does not respond to ligand presence. |
Revision as of 12:03, 14 October 2019
Contents
Introduction
To validate the designed constructs we decided to test Theophylline switch-off (stop auto-cleavage in presence of ligand). For negative control, we choose an inactive form of aptazyme: mutation at the ribozyme domain. iGEM Strasbourg designed construct requires the use of aptazyme linked to MS2 and PP7 stem-loops. The following results described MS2-MS2-Aptazyme-PP7-PP7 activity in in-vitro and in-vivo assays.
In-vitro assay of BBa_K2923018
In order to check MS2-MS2-Theophylline-PP7-PP7 cleavage activities, in-vitro transcription products were analyzed by 2% agarose gel with urea (Figure 1).
In-vitro assay show, that PP7-PP7-Theophylline-MS2-MS2 constructs have kept 100% of their ribozyme activity. Also, inactive aptazyme did not present aptazyme catalytic activity, which confirms their use as efficient negative control.
In-vivo: ß-galactosidase assay in the absence of ligand
Before to start an in vivo experiment on aptazymes, we characterized the constructs created by Berry KE and Hochschild as positive and negative controls. A ß-galactosidase activity positive control also called BH3 corresponds to BBa_K2923000. A ß-galactosidase activity negative control, called BH2 correspond to an empty plasmid backbone.
Theophylline aptazyme is switch-off (self-cleaves in absence of ligand) and prevents ß-galactosidase transcription. It was analyzed in the presence of its inactive form and BH2, BH3 controls (Figure 2).
Theophylline aptazyme has a ß-galactosidase activity profile similar to BH2 and BH3 controls, which promotes its use as a ligand sensor in the designed three-hybrid system. This data confirms that aptazymes could be compatible with three-hybrid systems.
In-vivo: ß-galactosidase assay in the presence of ligand
For investigating theophylline aptazyme in vivo activity we choose concentration recommended of Theophylline ligand by Felletti et al., 2016: 2,5 mM. We performed the ß-galactosidase assay in the presence of its negative control and BH2/BH3 controls incubated with the same concentrations of theophylline (Figure 3).
We obtained the expected results for all controls, but theophylline ligand did not have effects on the three-bacterial hybrid system. Despite that, the active form of theophylline aptazyme is not sensitive to its ligand. Any significant ß-galactosidase activity increase was observed in the presence of Theophylline ligand compared to an inactive control.
To increase the chances to obtain positives results for Theophylline aptazyme we choose to perform the same experiment with a higher concentration of Theophylline ligand (5mM) (Figure 4).
However, the obtained results show that Theophylline does not respond to ligand presence.
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