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Overview
To incorporate quorum sensing part, inhibition part, and restoration part into E. coli, we first built up the gene construct and expressed red and green fluorescent proteins to know our biobricks can be successfully expressed, and test their functions to prove the proteins secreted by DenTeeth can work. Finally, we designed an experiment to ensure the biosafety of DenTeeth.
Gene Construct
We incorporate quorum sensing part, inhibition part, and restoration part into E. coli BL21(DE3). We did colony PCR and digest to check its genotype.
Protein Expression
Mechanism introduction
LuxR protein will induce Plux promoter in Seq-B when the environment temperature is over 37 degrees Celcius and the total bacteria number in the environment is high. After the Plux promoter in Seq-B was induced, LL-37 antimicrobial peptides, tetR protein, and RFP would express.
On the other hand, when the total bacteria number in the environment is low, without the inhibition of tetR, Ptet promoter in Seq-C would be induced and express BMP2, STATH, and GFP.
Functional Test
LL-37 Functional Test
After finishing the design of DenTeeth, we wanted to know whether its inhibition ability can have a function, so we designed the following experiment. Our team decided to use the inhibition zone experiment to confirm that DenTeeth can inhibit other bacteria. Furthermore, we can also compare the difference of inhibition zone diameter to know the strength of inhibition intensity.
STATH Functional Test
After making STATH successfully translocated onto the inner membrane of our DenTeeth, we want to know whether the function of STATH works in our DenTeeth.
STATH can prevent the precipitation of calcium phosphate in saliva and maintain a high calcium level in saliva. Therefore, STATH is available for promoting the remineralization of tooth enamel and preventing calculus formation.
Calcium Attachment Test
To test whether the STATH expressed by DenTeeth had the function, we decided to detect the calcium ions concentration change with the STATH property of binding to the surface of hydroxyapatite (HA), preventing the calcium ion from attaching to HA. Due to HA being the main component of enamel in teeth, we want to use HA to simulate the oral condition. However, the calcium ion concentration change was too small to detect, and no vendor could provide us HA in time, resulting from the impact of Covid-19.
After the consultation with prof. Hsiao-Ching, Lee, we came up with a replacement plan, observing the attachment of calcium ions on the carbon rod surface. Carbon rods are processed to have small, low-volume pores that increase the surface area available for adsorption. We expected that both STATH and calcium could adsorb on the surface of carbon rods, so we designed a test to observe the surface of carbon rods soaked in different solutions under the microscope.
We made four solutions configured to calcium ions saturated solutions by the calcium chloride solution, ddH2O, LB broth, DenTeeth, and E. coli with pSB1K3, in the tubes with the carbon rods stuck inside. After putting them into a 0°C refrigerator for 12 hours, the solutions would become calcium ions supersaturated solutions. In the DenTeeth, STATH would bind onto the surface of the carbon rod, preventing the calcium ions from binding onto it.
As for the precipitation on the bottom of tubes was the debris of bacteria, which was died of the broken cell membrane caused by the high concentration of calcium chloride solution.
The result in the following figure showed that the surface of the carbon rod taken out of the DenTeeth was matte compared with that in other solutions. We presumed that the result was due to the protective layer on the surface formed by the STATH that would prevent the liquid from attachment.
We can see the different conditions of calcium attachment on carbon rods after soaking in different calcium ions saturated solutions overnight in Figure 6.
Picture A in figure 6 is the original carbon rod. We can observe many layer-like structures on its surface clearly. Since the original carbon rod hadn't soaked in any solution, no crystal of calcium can be seen on its surface. However, without soaking in any solution, there is some little dust smaller than crystal particles on its surface.
Picture B is the original carbon rod soaked in calcium ions saturated ddH2O. Obvious white particles can be observed on its surface. We presume the particles might be the crystal of calcium.
Picture C is the carbon rod soaked in calcium ions saturated LB Broth. There is a relatively big particle on the surface, in our opinion, is formed by calcium crystals.
The carbon rod soaked in calcium ions saturated E. coli DenTeeth is shown in Picture D. With STATH functioning, there are no particles be seen on the surface of the carbon rod and the surface remains clear. Besides, the surface of it is even cleaner than the original carbon rod. We suppose that is because this rod has been soaked in the solution, which will bring away the dust on its surface.
Carbon rod soaked in calcium ions saturated E. coli BL21(DE3) with pET32a. We chose this colony as one of our control groups since it has the same Kanamycin resistance as DenTeeth. There are many particles on its surface, which might be composed of calcium crystals.
Feeding Frequency Verification
Safety
To prove that DenTeeth can be inhibited by gastric acid, we conducted an Inhibition of Growth of DenTeeth Test. Because the HCl concentration of the animal's gastric acid ranged from 0.15M to 0.05M, we added 200μL HCl(aq) from 0.3M to 0.1M with equal DenTeeth and observed whether the DenTeeth in different concentrations of HCl(aq) would be inhibited. In addition, we chose ddH2O and HClO(aq) as our negative control and positive control, respectively.
The DenTeeth's biobrick could successfully degrade in any range from 0.1M to 0.3M HCl(aq). Only the sample added with ddH2O has the band in 4685 b.p., which was the length of our biobrick. The cloning result proved that the biobrick could not have the chance to transfer to another bacteria.
Reference
- Schink, S. J., et al. (2019). "Death rate of E. coli during starvation is set by maintenance cost and biomass recycling." 9(1): 64-73. e63.