Team:ETH Zurich/Decoder/Results

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* XbaI & PstI.
* XbaI & PstI.
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[[File: Geldigestpaba2012debbie.png|frameless|350px|right|thumb|''Fig.1.'': Digests left to right: Ladder, <partinfo>BBa_K909014</partinfo> (NheI/PstI), <partinfo>BBa_K909014</partinfo> (XbaI,PstI),<partinfo>BBa_K909015</partinfo> (NheI/PstI), <partinfo>BBa_K909015</partinfo> (XbaI,PstI).  ]]
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[[File: Geldigestpaba2012debbie.png|frameless|350px|center|thumb|''Fig.1.'': Digests left to right: Ladder, <partinfo>BBa_K909014</partinfo> (NheI/PstI), <partinfo>BBa_K909014</partinfo> (XbaI,PstI),<partinfo>BBa_K909015</partinfo> (NheI/PstI), <partinfo>BBa_K909015</partinfo> (XbaI,PstI).  ]]
[[File: Pabamap.png|frameless|250px|right|thumb|''Fig.'': Plasmid map of <partinfo>BBa_K909014</partinfo> in pSB1C3. ]]
[[File: Pabamap.png|frameless|250px|right|thumb|''Fig.'': Plasmid map of <partinfo>BBa_K909014</partinfo> in pSB1C3. ]]

Revision as of 18:36, 26 September 2012

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Navigate through Overview, Design and Results

Contents

Dual input promoters

We succesfully cloned the dual input promoters. Results can be found on the partsregistry.

PABA generator

We were succesful in constructing both parts <partinfo>BBa_K909014</partinfo> (2699bp) and <partinfo>BBa_K909015</partinfo> (2656bp) based on the already existing parts <partinfo>BBa_K137055</partinfo> and <partinfo>BBa_S04039</partinfo>. The vector backbone is <partinfo>pSB1C3</partinfo> (2079bp). They differ from each other due to the fact that <partinfo>BBa_K909014</partinfo> contains the constitutive promoter <partinfo>BBa_J23100</partinfo> with two NheI restriction sites.

To verify the sizes of the constructs, the plasmids containing <partinfo>BBa_K909014</partinfo> and <partinfo>BBa_K909015</partinfo> were digested with

  • NheI & PstI
  • XbaI & PstI.
Fig.1.: Digests left to right: Ladder, <partinfo>BBa_K909014</partinfo> (NheI/PstI), <partinfo>BBa_K909014</partinfo> (XbaI,PstI),<partinfo>BBa_K909015</partinfo> (NheI/PstI), <partinfo>BBa_K909015</partinfo> (XbaI,PstI).
Fig.: Plasmid map of <partinfo>BBa_K909014</partinfo> in pSB1C3.
Fig.:Plasmid map of <partinfo>BBa_K909015</partinfo> in pSB1C3.












TOP10 cells were transformed with the construct and the content of Pab exijijefwjioaaalame <partinfo>BBa_K909014</partinfo> <partinfo>BBa_K137055</partinfo> PabA <partinfo>BBa_S04039</partinfo> PabB/C l

Plans

Cloning of <partinfo>BBa_K909015</partinfo> downstream of the PL dual input promoter <partinfo>BBa_K909011</partinfo> containing the TetO1 and LacO1 operator sites and implementation.


Outlook

After assembling all parts for the decoder, we want to test the circuit by simulating blue and red light with aTc and IPTG. Our output system is based on fluorescent proteins (eYFP, mCherry and GFP) giving us the possibility to analyse the result by single cell analysis (FACS).

Figure: Boolean logic for testing of Decoder.


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