<p>Promoters are a region of DNA that initiates transcription of a specific gene. In bacteria, promoters contain 2 short sequence elements about 10 and 35 nucleotides upstream from a transcription start site. For our project, we utilize inducible promoters to initiate the transcription of regulator proteins and inducible GFP signals. Inducible promoters are a power tool in genetic engineering because the expression of genes operably linked to them can be turned on or off at certain stages of development of an organism or in a particular tissue [1] This allows us to track and analyze data to find orthogonality between senders and receivers. This is done when senders produce acyl-homoserine signals (AHLs) and attach to a regulator promoter in the corresponding receiver system. This allows for DNA binding and transcription initiation. This in turn allows for proteins to be made which then bind to the inducible promoter to allow GFP to be turned on. If there is no transcription of our regulator gene, aka no AHL attachment to the promoter of the regulator protein,  our system won’t turn on. This will allow our team to run various experiments and see if it is working. This particular production of HSLs is just one one type of quorum sensing system out there and the type of system that is utilized in this project. We can test our system of senders and receivers for orthogonality by setting up induction experiments with different sender signals. A positive result means the sender signal will only turn on the GFP signal of one regulator gene, meaning the GFP is expressed in the system. </p>

<p>Our team came across a paper by Spencer R Scott and Jeff Hasty from UC San Diego. They designed new inducible promoters that lead to better expression and easier cloning in their specific AHL related QS systems [2]. Due to this, our iGEM team utilized their thought and design process into our systems. The goal of our project is to successfully incorporate inducible promoters into our system to have them respond to HSLs and induce expression of GFP in E.coli. In addition, we hope to find undiscovered orthogonality between our senders and receivers. Hybrid promoters Ptra* and Prpa* were created by replacing the lux-box in the commonly used PluxI promoter with the tra-box and the rpa-box, respectively [2]. Using this idea, we created new receivers for our system with tra, rpa, and las genes to test in our experiments. In addition to this, new receivers of Bja [4], Aub [3], and Rhl [5] were created for testing. This was done by having a promoter from Lux and combining it with the specific regulator gene binding domain [2]. In addition to the inducible promoter, we also rearranged to order of our two part receiver system. The regulator and GFP were originally in that respective order. However, in our new receivers that orientation is switched. This was due to finding a leaky expression due to transcriptional read through of the receiver. By swapping the order, we can optimize the sequence to avoid transcriptional read through in our reporter gene. </p>

<p>Brautaset, Trygve, Rahmi Lale, and Svein Valla. “Positively Regulated Bacterial Expression Systems.” Microbial biotechnology 2.1 (2009): 15–30. PMC. Web. 8 Sept. 2017.

Scott, S. R., and J. Hasty. "Quorum Sensing Communication Modules for Microbial Consortia." ACS Synth Biol 5.9 (2016): 969-77. Web. 8 Sept 2017.  

Nasuno, E., et al. "Phylogenetically Novel Luxi/Luxr-Type Quorum Sensing Systems Isolated Using a Metagenomic Approach." Appl Environ Microbiol 78.22 (2012): 8067-74. Web. 9 Oct. 2017.

Lindemann, Andrea et al. “Isovaleryl-Homoserine Lactone, an Unusual Branched-Chain Quorum-Sensing Signal from the Soybean Symbiont Bradyrhizobium Japonicum.” Proceedings of the National Academy of Sciences of the United States of America 108.40 (2011): 16765–16770. PMC. Web. 9 Oct. 2017.