I.Light control system

We have done the experiments to examine the function of our light control system. Our light control system aims to switch between expression states to express different proteins according to different lights. There are two components: light-controlled promoter and a Not Gate. Firstly, we will show the light controlled promoter works and then add a Not Gate to prove that the whole pathway can work.

1.Light-controlled promoter —CcaS/R system+PcpcG

Since our light controlled promoter PcpcG is regulated by CcaR ,which can be phosphorylated by CcaS, and CcaS is the protein that can sense the light(activated by green light and ceased by red light). We must express this two proteins before use the PcpcG promoter. To test this system, we use GFP as indicator.

Firstly, we transformed four plasmids to E.coli and added IPTG to induce the expression of the Ccas and Ccar. Then, we examined the GFP expression.

1.lac operator + Ccar + Ccas (As negative control)

2.lac operator + Ccar + Ccas + Cpcg (light control promotor) + green fluorescence protein

3.lac operator + Ccar + Ccas + Cpcg (light control promotor) + TetR + TetO + green fluorescence protein

4.constitutive promotor + GFP (As positive control)

Inevitably, the light control switch had a leaky expression, but the leakage was low in a certain period of time.

Then, we cultivated the induced E.coli under green light, red light and darkness for 2h, and examined GFP expression.

The bacteria transformed with light control system and GFP had obvious increasing in fluorescence intensity after activated by green light and the negative control (only have the light control system) had the similar fluorescence intensity under different lights.

After that, we transformed the green light into red light, vice versa. We kept the bacteria in darkness dim and cultivated them for 1h to examine the GFP expression.

After transforming the light, we can see the fluorescence intensity were changed dependent on the different lights. Positive control and Negative control had similar data in all kinds of light. But light control system play significant role in the expression of GFP under different light conditions. In conclusion, red light can cease the PcpcG, and green light can re-start the pathway ceased by red light. That suggests our promoter can work cyclically.

2.Light-controlled promoter + Not Gate pathway

We did this pathway experiments together with the light controlled promoter, and now we can focus on the blue one:

The bacteria transformed with light control system , not gate and GFP had a few increasing in fluorescence intensity in the red light and darkness. What’s more, The fluorescence intensity in green light had a relative lower fluorescence intensity compared with the samples that got before activated by light.

In the transforming light experiment, the not gate play significant role in the expression of GFP to reverse the trend.

Conclusion: The verification of the entire pathway illustrates the coupling of the light-controlled promoter and the Not Gate, and preliminarily demonstrates that our system can work cyclically. Although in this experiment, the data is still not perfect. Factors such as expression time should be considered more in subsequent experiments.

II.Functional proteins to collect Phosphorus

Since we decided to take phosphorus as example, we must find the functional proteins to be controlled by the PcpcG and Not Gate. Two functional opposite protein can do this job, One to accumulate the Phosphorus from the environment and the other release them to the Ark. We found PPK to accumulate, and PPX to release. Later we add a part-PPN to strengthen the efficiency of PPX. In this section, we will test the function of these three proteins.

1.PPK—phosphorus accumulation

After a careful information retrieval, we decided to choose the Polyphosphokinase (PPK) from Team Manchester_2017 and we test the efficient of it again.

Firstly, we found that this PPK gene originally exists in our E.coli.

This suggested that PPK protein is compatible in our chassis, and transformation of the PPK was actually an overexpression.

Then, we tested the function of PPK, We did this through measuring the change in phosphorus concentration in the medium. And we made a calibration curve before.

This experiment verifies that BL21 transferred to the pET28a plasmid containing PPK has a certain phosphorus-concentrating effect, and it is not caused by bacterial growth and natural PPK.

2. PPX,PPN—phosphorus release

We refer to PPX’s data from the Team 15_York. Because our system requires faster and more complete release of phosphorus, we added PPN as a protein to assist in the release of phosphorus. Thus we built PPX+PPN pathway.

PPN is a protein that originally comes from Saccharomyces cerevisiae, before the function test, we must verify that PPN protein can be expressed in E. coli.

We demonstrated that PPN can be expressed in E. coli by gel electrophoresis experiment.

Then, we use the same method to test the function of PPX + PPN.

By induction 2, its average phosphorus uptake capacity is significantly reduced, indicating that phosphorus is released.

Because of the growth of the bacteria, it is difficult to see the dramatic changes of phosphorus concentration of the medium. Thus we used the staining method - PolyP is metachromatic granules in the bacteria, which can be stained. It is possible to judge whether or not PolyP is present in the bacteria by staining to determine whether our protein is functional.

We use Albert stain for metachromatic granules, and PPX and PPN have the ability to release phosphorus from E. coli, respectively. It can be seen that BL21, which has not been transferred into the gene, shows a distinct blue color, indicating the presence of the heterochromatic granules; while the E. coli that was transferred to PPN and PPX, respectively, was not stained blue, demonstrating the release of phosphorus.

Conclusion: we proved that PPK,PPX,PPN both had the function and PPN can additionally enhance the ability to release the phosphorus.

III.Pathway for bio-safety—kill switch

To prevent bacterial leakage, we designed two toxin-antitoxin pathways to ensure that bacteria will commit suicide once they escape from the environment we provide. We use riboswitch to identify the different environment, antitoxic is continuously expressed but it can’t prevent the killing effect of toxins on cells, unless the corresponding counterpart of the riboswitch, theophylline, is added, and the antitoxin can inhibit the toxicity of the background expression level of the toxin.

  Prefix + lac operator + parE+ riboswitch +parD + suffix

  Prefix + lac operator + MazE + riboswitch + MazF + suffix

1.MazF/MazE toxic-antitoxic switch

Because theophylline itself may be harmful to cells, as a substance that turns off the riboswitch, we first made a gradient dilution and found the mildest range for the bacteria.

Although we used a lower concentration of theophylline in this pathway, we finally found that this pathway did not work.

2. ParD/ParE toxic-antitoxic switch

We performed a second pathway validation with a lower theophylline concentration.

We can drew the results that this pathway can work and the best effect of theophylline concentration is 0.2g/L.