Part:BBa_K3457039

T7-RBS-SAHS 33020-T7-RBS-CAHS 106094

    This biological is the expression sequence of Cytosolic-abundant heat soluble protein 106094 (CAHS 106094) and secreted abundant heat soluble protein 33020 (SAHS 33020). They are two kinds of Tardigrade intrinsically Disordered Proteins (TDPs), heat soluble proteins found from Tardigrade Hypsibius dujardini in 2017 ^[1]. Tardigrade, also called water bear, is a kind of tenacious organism. It can survive extreme environment, such as desiccation, freeze and vacuum. The super capacity of Tardigrade partially owes to TDPs. We found that expressing CAHS 106094 or SAHS 33020 can help bacteria survive the freeze-drying process and then the resultant dry bacteria powder can be stored for a long time at room temperature. What's more, co-expressed the two proteins by this part gave a better protective effect.

Contribution

Group: QHFZ-China iGEM 2020

Author: Yixian Yang

Design & Improvement

Figure 1. The Schematic cartoon of the DNA construct.

    This part is a combination by two expression module and the two expressed protein has synergistic effect (Fig. 1). The part was constructed by biobrick ligation. Indeed, we constructed SAHS 33020 module into the vector first, then cut the vector by SpeI and PstI, cut the CAHS 106094 modelue by XbaI and PstI, at last used T4 ligase to ligate the two fragments.

Compared with the existing art, it can express one more useful protein. In addition, we also added lacO sequence after the T7 promoter, so that the expression could be controlled by adding iPTG; we added a 6x His tag sequence at the 5' end of the CDS of the two protein for convenient detection by western Blot.

Documentation:

Introduction:

    This year, we tried to introduce a new biopreservation method. We used freeze-drying to make the engineered into dry powder. Then the powder can be stored at room temperature for a long time. This method can make the storage of bacteria get rid of ultra-low temperature freezer, so that it will promote the practical application of engineered bacteria out of laboratory. However, the stresses during freeze-drying and subsequent dry storage, including freeze, dry and vacuum, are lethal to bacteria. We use TDPs to help bacteria survive the situation. In the past, for the stuy with live cells, all people studied drying live cells, so we are the first to study freeze-drying live cells.

    However, though single TDP could enhance the survival rate druing freeze-drying process and subsequent dry storage, the survival rate should be further enhanced. As far as we knew from Human Pratices, the current survival rate of bacteria after freeze-drying is around 10%, even great protective agents are added and advanced freeze-drying protocol is used. We can imagine that on this basis, if single TDP is added, the survival rate would be ehanced. However, it is not very realistic to reach 50%, 80% or 90%. As a result, the method (adding TDP) should be further improved.

Figure 2. Co-expressing SAHS 33020 and CAHS 106094 to protect engineered bacteria.

    Tardigrade co-expresses many TDPs to survive the drought. The proteins may have some supplementary effect, because the structures are not the same. However, no one studied co-expressing them before. Here we tried to combine two TDPs (Fig. 2) and get a better result than expressing single TDP.

Protocol:

    To test the effect of this part, we modified a frequently and widely used vector, pet28a+ and put this part into it (Fig. 3). Then we transformed the plasmid into E. coli BL21 strain.

Figure 3. The Schematic cartoon of the vector.

    Then we used the following protocols to verify its function (Fig. 4):

Figure 4. Experiment protocol.

【Day 1】Induction culture
(1) Pick clones which are in good condition and put them into 500 μL LB medium containing antibiotics. Shake them to grow at 37℃ for 5~7 hours until the bacteria solution becomes turbid.
(2) Add 2 mM iPTG into 3 mL LB medium containing antibiotics. Add 3 μL of the bacteria solution mentioned in step 1 to dilute the bacteria by the ratio of 1:1000. Shake the solution to grow the bacteria at 37℃ overnight.
【Day 2】Freeze-dried
(1) If fluorescence induced by the iPTG is detectable in the control group (GFP), continue conducting the experiment.
(2) Use spectrophotometer to measure the OD₆₀₀ of the bacteria solution, OD₆₀₀ = 1 equals to 10⁹ cells. If the OD₆₀₀ value is between 0.1 and 1, There is a linear relationship between OD₆₀₀ and bacterial density. Calculate the volume of bacterial solution for 10⁹ cells by using the formula V = 100 / (OD₆₀₀ × Dilution ratio).
(3) Take out a measured amount of 10⁹ cells and centrifuge it at 8000 rpm for 3 min. Then pour out the supernatant.
(4) Resuspend the bacteria in a 15 mL tube with pre-refrigerated 100 μL 3% glucose solution.
(5) Take off the cover of the tube and put the bacteria into the cold trap. Open the compressor of the lyophilization machine and freeze the shake tube for 2 h at -70℃.
(6) Put the caky bacteria solution into the drying chamber of the lyophilization machine. Open the vacuum pump to dry it in vacuum for 6h at 1 Pa vacuum degree.
(7) Turn off the vacuum pump, place it at seal box filled with silica-gel desiccant a for 2 days at room temperature.
【Day 3】Room temperature storage
【Day 4】Detect the survival rate
(1) Add 1 mL of sterile water to the tube, vortex for 15 s, placed it at room temperature for 10 min.
(2) Adjust the density of the bacteria solution by gradient dilution, then spread 100 μL of the bacteria solution on the LB plate.
(3) If the density above is not suitable, take 100μL of the solution and spread it on the LB plate after several gradient dilutions.
(4) Culture the bacteria overnight at 37℃.
【Day 5】Cell Count
(1) Take out the LB plate and take photos to record experimental results.
(2) Use the automatic cell counting function of Image J to count the colone number on the LB plate, then compare the results between each group.

Results:

    First, by a reporter, sfGFP, we confirmed that the plasmid can normally expressed exogenous proteins in E. coli BL21 strain (Fig. 5). Via SDS-PAGE, we observed the band of CAHS 106094, further verified the successfully expression (Fig.6).

Figure 5. Via a reporter, sfGFP, the expression function of the modified pet28a vector was verified.

Figure 6. SAHS 33020 and CAHS 106094 were expressed. In the SDS-PAGE, the band of SAHS 33020 is not quite clear. So we added a Western Blot test to show it.(Western was did in another lab by a perosn out of our team.)

Then, by freeze-drying and recover experiment, we found that compared with the control group (sfGFP), the bacteria expressing SAHS 33020 or CAHS 106094 had a better survival rate, while co-expressing the two proteins gave a better survival rate than that of expressing single TDP (Fig. 6).

Figure 6. SAHS 33020 + CAHS 106094 protected bacteria during freeze-drying and subsequent dry storage.

The dry storage time is 2 days, which is a litte short. So we waited for another 10 days to test if TDPs work in long-term storage. In accord with the result above, co-expressing two TDPs gave the best survival rate. (Fig. 6).

Figure 7. SAHS 33020 + CAHS 106094 protected bacteria during long-term dry storage.

Summary:

    CAHS 106094 helps the bacteria survive freeze-drying and subsequent dry storage. Additional SAHS 33020 can collaborate with CAHS 106094 and gave a bettereffect. To achieve that, you need only to transform the sequence into your bacteria.

Reference:

[1] Boothby, T.C., Tapia, H., Brozena, A.H., Piszkiewicz, S., Smith, A.E., Giovannini, I., Rebecchi, L., Pielak, G.J., Koshland, D., and Goldstein, B. (2017). Tardigrades Use Intrinsically Disordered Proteins to Survive Desiccation. Mol Cell 65, 975-984 e975.

Sequence and Features