Team:UNAM Genomics Mexico/Project/DeeperDescription

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UNAM-Genomics_Mexico


Under Construction




Nanotubes!!

The logic

Random info

Deep Description



Our boolean constructions are two, the AND & OR, for it to form a system, but how we will connect this two operations? With the nanotubes that Bacillus subtilis form.

Why B. subtilis?
We found a paper in which Ben-Yehuda et. al. demostrated that Bacillus subtilis form nanotubes between them, Escherichia coli and Staphylococcus aureus. And they were able to get through a GFP and some other smaller molecules. So, we decided to use this connection to form the principles of a molecular computer. How? The output of the first operation will the input for the next one, and that was what we did. Also, there is not many work in the B. subtilis at the iGEM competition, so we decided to standardize the protocols of competent cells and transformation, and to send biobricks that B. subtilis could transform and integrate for them to work correctly (link al new standar protocol).

  • 2011 Gyanendra P. Dubey, Sigal Ben-Yehuda. Intercellular Nanotubes Mediate Bacterial Communication. Cell, 2011; 144 (4): 590 DOI:10.1016/j.cell.2011.01.015

  • 2011 Gyanendra P. Dubey, Sigal Ben-Yehuda. Intercellular Nanotubes Mediate Bacterial Communication. Cell, 2011; 144 (4): 590 DOI:10.1016/j.cell.2011.01.015



How does the AND work?

The AND operator in general, locate records containing all of the specified search terms. In the design, we considered the possibility that the constitutive promoter could continue with transcription even after getting to the double terminator and to avoid this, we designed the AND construction with the inducible promoter before the constitutive one.
We have two types of AND:
•The Heavy Metals AND: The promoters CzrA/ArsR have something in common, they both sense cadmium. When the two promoters detect cadmium, they would not repress anymore and start transcription of P4 or LasR, and we will know it is working because our bacterium will be red, because of our reporter gene (RFP). The promoters are based in the CadA promoter plus a binding site for ArsR for get a response that depend in both, CzrA and ArsR.

•CzrA/ArsR: This transcription factors are involved in metal homeostasis, each one had affinity for a set of metals[1], the intersection of both sensors is Cadmium[2][3], in this case the proposed input metals will be Zinc for CzrA and Arsenic for ArsR. This TFs acts as repressors in the absence of metals, when there is metal in the cell, the metal binds to the transcription factor and make a conformation change that dissolves the affinity of the protein for their binding sites and let the promoter free to recruit RNA polymerase to start transcription[1].

•P4: It´s a transcription factor from phi29 phage, which is a phage of B. subtilis, it is the activator of the A3 promoter[4,5].

•LasR: It is another activator transcription factor, its origin is Pseudomonas aeruginosa PAO1, its correspondent promoter is LasB[20].

•CI: This protein is a repressor from Lambda phage.

•RFP: highly engineered mutant of red fluorescent protein from Discosoma striata (coral), this is our reporter gene[6].

•Omega cassette: The Omega Cassette provides resistance to Spectinomycin and Streptomycin; it was obtained from plasmid pHP45omega[7,8]. Specifically, the resistance is provided by the aminoglycoside antibiotic resistance gene (aadA +) originally carried on a 1.7-kb PvuII-HindIII fragment from the R100.1 plasmid[8].

•AmyE: Integration sequences allow DNA to be incorporated into the chromosome of a host cell at a specific locus. This is achieved by using leading (5') and trailing (3') DNA sequences that are the same as those at a specific locus of the chromosome. The 5' integration sequence(BBa_K143001) can be added to the front of a BioBrick construct and the 3' integration sequence specific for this locus (BBa_K143002) to the rear of the Biobrick construct to allow integration of the BioBrick construct into the chromosome of the Gram-positive bacterium B. subtilis at the amyE locus[18,19].