Team:PKU Beijing/Project/AND Gate 2 Design

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(Another Design of the Second AND Gate)
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First, we should figure out the -35 region and the -10 region of the salicylate inducible promoter. Then, the region between -35 and -10 is replaced with a CI434 binding site. Another CI434 binding site is placed downstream of -10 region. In this way, the promoter is silenced when CI434 is bound. After CI434 is removed from the system, this hybrid promoter still needs salicylate to activate.
First, we should figure out the -35 region and the -10 region of the salicylate inducible promoter. Then, the region between -35 and -10 is replaced with a CI434 binding site. Another CI434 binding site is placed downstream of -10 region. In this way, the promoter is silenced when CI434 is bound. After CI434 is removed from the system, this hybrid promoter still needs salicylate to activate.
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[[Image:PKU_Second_AND_Gate_Hybrid_Promoter.png|600px|center|thumb|fig3. Another Design of the Second AND Gate]]
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[[Image:PKU_Second_AND_Gate_Hybrid_Promoter.png|400px|center|thumb|fig3. Another Design of the Second AND Gate]]
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Revision as of 16:31, 13 October 2009

 

One of the Second AND Gate Design


Primarily we have 2 alternative design of the second AND Gate. One of the them employs the same mechanism as the first AND Gate. However, the activator is not T7 polymerase, it is a different activator with amber mutation of its Ser codon. Actually, we picked two candidates activator proteins. One of them is from partsregistry 2009 distribution, the PhiR73 delta activator and corresponding promoter PO promoter. The other is T3 polymerase and its promoter T3 promoter.

fig1. One design of the second AND Gate


One of the input to the second AND Gate is from the ring signal. Because both of the AND Gates share the ring signal input, SupD tRNA is shared from AND Gate 1. The second AND Gate is intact only when coupled to the first AND Gate. The other input to the second AND Gate, of course, is from the memory module, we put a CI434 repressible and CI inducible promoter upstream of the PhiR73 delta/T3pol (amber mutation)protein.

When the bistable switch is in the “NO MEMORY” state, namely the CI434 state, PhiR73 delta/T3pol (amber mutation) mRNA is not expressed. At this time, ring signal alone, though expresses SupD tRNA, has no effect. When the bistable switch is turned to the “MEMORY” state, with the constitutive expression of CI and the increase of PhiR73 delta/T3pol mRNA level, the ring signal can lead to expression of functional PhiR73 delta/T3pol by rescuing the amber mutation in the PhiR73 delta/T3pol protein.

In order to creat a amber mutation inside of the PhiR73 delta/T3pol coding sequence, we carried out site directed mutagenesis with primers introduced with TAG amber mutation at the original Ser site.

fi2. Creating the Amber mutation

Another Design of the Second AND Gate

Another design of the second AND Gate is to make a hybrid promoter, which can be activated by salicylate, and repressed by CI434. This hybrid promoter regulates the expression of PhiR73 delta/T3pol (this time, no amber mutation).


Because what we take is the first strategy, the second design is just discussed briefly below:


First, we should figure out the -35 region and the -10 region of the salicylate inducible promoter. Then, the region between -35 and -10 is replaced with a CI434 binding site. Another CI434 binding site is placed downstream of -10 region. In this way, the promoter is silenced when CI434 is bound. After CI434 is removed from the system, this hybrid promoter still needs salicylate to activate.

fig3. Another Design of the Second AND Gate




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