Introduction & Background

For our main system to work, where production of a biomaterial, only occurs when two specific lights intersect, a logic-gate needed to be developed. To create a NOR-gate at the promoter level, we aimed at creating dually repressed promoters. Most of NOR-gate promoter designs using tandem repressible promoters (1, 2, 3) have unpredictable properties and leaky expression. The main challenge to create a clean design of NOR-gate containing only one transcription starting point is the lack of standard transcriptional elements smaller than repressible promoters. Recent work on transcription elements showed that assembling insulated synthetic operator upstream and downstream of an insulated T7 promoter core allowed for a more diverse control of gene expression and a more specific response time (1).

Design

Figure 1: Design of the system to test dually repressible promoters. Each promoter is composed of at least two different operators (in blue) recognized by specific repressors and regulates the expression of a reporter gene (mRFP1 in red). A - Only one copy of each repressor is present downstream of the promoter core. B - A copy of one of the two different operators is present upstream of the promoter core to possibly enable a better control of gene expression.

Based on our modeling results, we designed decided to work of three specific repressors due to their interesting parameter values. For each pair of repressors, four different arrangements of the operators were characterized experimentally. Firstly, the impact of the way the two operators are ordered downstream of the promoter core was studied (Figure 2A). Secondly, we studied the impact of adding a second operator upstream of the promoter core on promoter activity (Figure 2B). This gave us a total of twelve promoters to test (Table 1).

Table 1: Dually repressible promoters designed for this study

Part number	Part Name	Sequence	Size
BBa_K2510018	T7 - O-HKcI - O-P22c2 promoter	GTAATACGACTCACTATAGGGGTGAACCATAAGTTCAGCTCTGATTTAAGTGTTCTTTAATCGCTGTTCCGCTG	74
BBa_K2510019	T7 - O-HKcI - O-TetR promoter	GTAATACGACTCACTATAGGGGTGAACCATAAGTTCAGCTCTGTCCCTATCAGTGATAGAGATCACACTCCTTC	74
BBa_K2510020	T7 - O-P22c2 - O-HKcI promoter	GTAATACGACTCACTATAGGGGATTTAAGTGTTCTTTAATCGCTGTTCCGCTGTGAACCATAAGTTCAGCTCTG	74
BBa_K2510021	T7 - O-P22c2 - O-TetR promoter	GTAATACGACTCACTATAGGGGATTTAAGTGTTCTTTAATCGCTGTTCCGCTGTCCCTATCAGTGATAGAGATCACACTCCTTC	84
BBa_K2510022	T7- O-TetR - O-HKcI promoter	GTAATACGACTCACTATAGGGGTCCCTATCAGTGATAGAGATCACACTCCTTCTGAACCATAAGTTCAGCTCTG	74
BBa_K2510023	T7 - O-TetR - O-P22c2 promoter	GTAATACGACTCACTATAGGGGTCCCTATCAGTGATAGAGATCACACTCCTTCATTTAAGTGTTCTTTAATCGCTGTTCCGCTG	84

Part number	Part Name	Sequence	Size
BBa_K2510024	O-HKcI - T7 - O-HKcI - O-P22c2 promoter	GTGAACCATAAGTTCAGCTATGTAATACGACTCACTATAGGGGTGAACCATAAGTTCAGCTCTGATTTAAGTGTTCTTTAATCG CTGTTCCGCTG	95
BBa_K2510025	O-HKcI - T7 - O-HKcI - O-TetR promoter	GTGAACCATAAGTTCAGCTATGTAATACGACTCACTATAGGGGTGAACCATAAGTTCAGCTCTGTCCCTATCAGTGATAGAGAT CACACTCCTTC	95
BBa_K2510026	O-P22C2 - T7 - O-P22C2 - O-HKcI promoter	GTCATTTAAGTGTTCTTTAATGAGCATCTGCTATGTAATACGACTCACTATAGGGGATTTAAGTGTTCTTTAATCGCTGTTCCGCTGTGAACCATAAGTTCAGCTCTG	107
BBa_K2510027	O-P22c2 - T7 - O-P22C2 - O-TetR promoter	GTCATTTAAGTGTTCTTTAATGAGCATCTGCTATGTAATACGACTCACTATAGGGGATTTAAGTGTTCTTTAATCGCTGTTCCG CTGTCCCTATCAGTGATAGAGATCACACTCCTTC	118
BBa_K2510028	O-TetR - T7 - O-TetR - O-HKcI promoter	GTCTCCCTATCAGTGATAGAGATCACACTCCTTCAACCTATGTAATACGACTCACTATAGGGGTCCCTATCAGTGATAGAGATC ACACTCCTTCTGAACCATAAGTTCAGCTCTG	115
BBa_K2510029	O-TetR - T7 - O-TetR - O-P22C2 promoter	GTCTCCCTATCAGTGATAGAGATCACACTCCTTCAACCTATGTAATACGACTCACTATAGGGGTCCCTATCAGTGATAGAGATC ACACTCCTTCATTTAAGTGTTCTTTAATCGCTGTTCCGCTG	125

Figure 2: Design of repressor expression device and reporter. A - First repressor and reporter regulated by P_lacIB - Second reporter and repressor regulated by P_Bad

Different input combinations were applied to the system, i.e. repressor concentrations were varied. In order to control concentration, the repressors were put under the control of well-known inducible promoters : p_lacI and p_ara. Since it is difficult to track the concentration of each repressor in real time, We designed the system presented in Figure 2 to be able to track repressor concentration using simple fluorescence.

In vivo testing

Testing of the promoters was performed in vivo in E. coli BL21 (AI) and E. coli BL21 (DE3). Both strains were tested to counter the effect of the T7 polymerase and at least one of the repressors being regulated by the same promoter. Analysis of fluorescence using a flow cytometer, testing four conditions for each strain: no inducer, each inducer indivudually - IPTG and arabinose - and both inducers together. The testing was performed on strains containing or not the repressors gene. The output measured is mRFP1 fluorescence and inputs ,i.e. repressor concentrations, are approximated by the concentration in fluorescent reporter protein - eyfp or ecfp. All florescences were measured using a flow cytometer.

Table of all the different conditions.

As is shown in figure 3, Red fluorescence is lower when either of the repressors are present in the system as well as when both are present (ttest,p<0.5). However, we can see that there is no cummulative effect of the presence of both repressors as the difference between the populations is not significant (ttest,p>0.5).

Cell-free testing using Photocaged repressors

We wanted to combine two aspects of our project: our designed logic gate and the photocaged repressors. We chose to test them in a cell-free environment for both practicality reasons and to show that every aspect of our project was compatible with a cell-free environment.

Team:Paris Bettencourt/Logic Circuit

Introduction & Background

Design

In vivo testing

Cell-free testing using Photocaged repressors