Difference between revisions of "Part:BBa K584015"
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<partinfo>BBa_K584015 short</partinfo> | <partinfo>BBa_K584015 short</partinfo> | ||
| − | We performed a '''PCR''' to get the '''CeaB''' part of the '''K131009 biobrick'''. The primer design for this was such that it already contained the ribolock resulting in | + | We performed a '''PCR''' to get the '''CeaB''' part of the '''K131009 biobrick'''. The primer design for this was such that it already contained the ribolock resulting in ‘'''Ribolock''' + '''ceaB'''’ as the final product. This is fused with the terminator B0015 to get ‘Ribolock + ceaB + B0015’. This was finally fused with the Lambda cI and LuxR regulated hybrid promotor to get this biobrick, ‘Lambda_cI and LuxR_regulated hybrid promotor’ + Ribolock + ceaB + B0015. |
The primer sequence we used in the PCR reaction is - | The primer sequence we used in the PCR reaction is - | ||
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ceaB-RV: AAAACTGCAGCGGCCGCTACTAGTCTCTAGTATTACTTACCCCGATGAATATCAATAT | ceaB-RV: AAAACTGCAGCGGCCGCTACTAGTCTCTAGTATTACTTACCCCGATGAATATCAATAT | ||
| + | |||
| + | '''Ribolock''' | ||
| + | |||
| + | The second part of the cell death mechanism of the K.U.Leuven iGEM 2011 project E.D. Frosti works via a ribokey-ribolock system. The ribokey is under the control of the HybB cold-sensitive promoter (BBa_J45503), which will only be switched on when E.D. Frosti senses a dramatic drop of the temperature. So when the ribokey isn’t transcribed, the ribolock mRNA will form a hairpin structure. Since ribosomes cannot access double stranded mRNA, there will be no translation of the CeaB gene. | ||
| + | |||
| + | Hence, to activate the cell death mechanism, E.D. Frosti needs to undergo a cold-shock treatment.E.D. Frosti will ‘sense’ the change in temperature and the ribokey will be transcribed. This ribokey will bind to the ribolock, followed by the opening of the double-stranded mRNA hairpin loop. Under these conditions, ribosomes can bind and translate the CeaB gene. '''CeaB''' is a DNase, which can be found in the Colicin E2 operon. | ||
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Revision as of 10:08, 19 September 2011
Lambda cI and LuxR regulated hybrid promoter + Ribolock-CeaB + Terminator
We performed a PCR to get the CeaB part of the K131009 biobrick. The primer design for this was such that it already contained the ribolock resulting in ‘Ribolock + ceaB’ as the final product. This is fused with the terminator B0015 to get ‘Ribolock + ceaB + B0015’. This was finally fused with the Lambda cI and LuxR regulated hybrid promotor to get this biobrick, ‘Lambda_cI and LuxR_regulated hybrid promotor’ + Ribolock + ceaB + B0015.
The primer sequence we used in the PCR reaction is -
ceaB-FW: CCGGAATTCGCGGCCGCTTCTAGAGAACTAGAATCACCTCTTGCTTTTGGGTAAGACGAAGAGGAGATACTAGATGAGCGGTGGCGATGGACGC
ceaB-RV: AAAACTGCAGCGGCCGCTACTAGTCTCTAGTATTACTTACCCCGATGAATATCAATAT
Ribolock
The second part of the cell death mechanism of the K.U.Leuven iGEM 2011 project E.D. Frosti works via a ribokey-ribolock system. The ribokey is under the control of the HybB cold-sensitive promoter (BBa_J45503), which will only be switched on when E.D. Frosti senses a dramatic drop of the temperature. So when the ribokey isn’t transcribed, the ribolock mRNA will form a hairpin structure. Since ribosomes cannot access double stranded mRNA, there will be no translation of the CeaB gene.
Hence, to activate the cell death mechanism, E.D. Frosti needs to undergo a cold-shock treatment.E.D. Frosti will ‘sense’ the change in temperature and the ribokey will be transcribed. This ribokey will bind to the ribolock, followed by the opening of the double-stranded mRNA hairpin loop. Under these conditions, ribosomes can bind and translate the CeaB gene. CeaB is a DNase, which can be found in the Colicin E2 operon.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]