Team:KULeuven/Lab/Vanillin Receptor
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- | = | + | =Planning= |
- | == | + | ==Goal== |
- | Besides producing vanillin, we would also like to control the concentration of vanillin outside of the bacteria. To do this, | + | Besides producing vanillin, we would also like to control the concentration of vanillin outside of the bacteria. To do this, we need a way to detect the vanillin extracellular and create a proper response intracellular. The vanillin sensing system receptor we propose, consists of the VirA/G system normally found in the Agrobacterium Tumefaciens. VirA is a receptor that responses to monosaccharides and phenols. Hence, it is able to sense vanillin. When binding vanillin, VirA is activated and will activate in its turn VirG. VirG is a transcription activator that will bind to a Vir box sequence in order to activate gene expression. This Vir box sequence can be found in the VirB promoter region. RpoA is a alfa subunit polymerase that is needed to help VirG work in E. coli. For extra literature see: Y.W Lee, S.Jin, W.S.Sim and E.W.Nester, ''Genetic evidence for direct sensing of phenolic compounds by the vira protein of agrobacterium tumefaciens''. Proc. Natl. Acad. Sci. U.S.A, 1995 december 19; 92(26): 12245–12249. |
- | == | + | ==Required== |
- | *Strains /isolated DNA of Agrobacterium tumefaciens: pTiBo542 and pTiA6NC/A1011 | + | *Strains/isolated DNA of Agrobacterium tumefaciens: pTiBo542 and pTiA6NC/A1011 |
*Biobricks: | *Biobricks: | ||
**{{kulpart|BBa_K238008}}: VirA | **{{kulpart|BBa_K238008}}: VirA | ||
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==Steps== | ==Steps== | ||
- | #The Agrobacterium strain is | + | #The Agrobacterium strain is plated out on agar from -80°C. From the other strain, DNA is expected to be sent. |
- | #The primers are used to perform a PCR on the bacteria or on the isolated DNA | + | #The primers are used to perform a PCR on the bacteria or on the isolated DNA to amplify the different genes or fragments (VirA, VirG, RpoA and virB promoter region). An agarose is performed as a control. |
- | #The PCR fragments are ligated in a TOPO | + | #The PCR fragments are ligated in a TOPO vector and electroporated into E. coli. |
#The plasmids are isolated via miniprep and again verified through restriction digest and agarose gel. | #The plasmids are isolated via miniprep and again verified through restriction digest and agarose gel. | ||
#Site directed mutagenesis (according to stratagene) is performed on RpoA and VirA to get the EcoRI and PstI restriction sites out. | #Site directed mutagenesis (according to stratagene) is performed on RpoA and VirA to get the EcoRI and PstI restriction sites out. | ||
#All parts are sequenced. | #All parts are sequenced. | ||
#The different plasmids (consideration: put in registry as separate part) are combined into one standard iGEM plasmid, with the appropriate promoter, RBS and terminators. | #The different plasmids (consideration: put in registry as separate part) are combined into one standard iGEM plasmid, with the appropriate promoter, RBS and terminators. | ||
- | #The system’s function is checked by linking a GFP to the virB-promoter region and | + | #The system’s function is checked by linking a GFP to the virB-promoter region and subsequent induction with Vanillin and Ferrulic Acid |
Latest revision as of 08:59, 13 August 2009
Contents |
Planning
Goal
Besides producing vanillin, we would also like to control the concentration of vanillin outside of the bacteria. To do this, we need a way to detect the vanillin extracellular and create a proper response intracellular. The vanillin sensing system receptor we propose, consists of the VirA/G system normally found in the Agrobacterium Tumefaciens. VirA is a receptor that responses to monosaccharides and phenols. Hence, it is able to sense vanillin. When binding vanillin, VirA is activated and will activate in its turn VirG. VirG is a transcription activator that will bind to a Vir box sequence in order to activate gene expression. This Vir box sequence can be found in the VirB promoter region. RpoA is a alfa subunit polymerase that is needed to help VirG work in E. coli. For extra literature see: Y.W Lee, S.Jin, W.S.Sim and E.W.Nester, Genetic evidence for direct sensing of phenolic compounds by the vira protein of agrobacterium tumefaciens. Proc. Natl. Acad. Sci. U.S.A, 1995 december 19; 92(26): 12245–12249.
Required
- Strains/isolated DNA of Agrobacterium tumefaciens: pTiBo542 and pTiA6NC/A1011
- Biobricks:
- VirA
- VirG
- RpoA
- VirB promoter region
- Primers:
For VirA, VirG, RpoA, VirB promoter region and for the site directed mutagenesis to remove unwanted restriction sites in VirA (PstI 2x) and RpoA (EcoRI 2x)
- TOPO-Vector or iGEM vector
Where from
- The primers were ordered
- The plasmids: from the lab
- One strain was ordered and another was available in the lab
Steps
- The Agrobacterium strain is plated out on agar from -80°C. From the other strain, DNA is expected to be sent.
- The primers are used to perform a PCR on the bacteria or on the isolated DNA to amplify the different genes or fragments (VirA, VirG, RpoA and virB promoter region). An agarose is performed as a control.
- The PCR fragments are ligated in a TOPO vector and electroporated into E. coli.
- The plasmids are isolated via miniprep and again verified through restriction digest and agarose gel.
- Site directed mutagenesis (according to stratagene) is performed on RpoA and VirA to get the EcoRI and PstI restriction sites out.
- All parts are sequenced.
- The different plasmids (consideration: put in registry as separate part) are combined into one standard iGEM plasmid, with the appropriate promoter, RBS and terminators.
- The system’s function is checked by linking a GFP to the virB-promoter region and subsequent induction with Vanillin and Ferrulic Acid