Summary

Protocol for Recombinant RBD-based SARS Vaccines: Protein Preparation, Animal Vaccination and Neutralization Detection

Published: May 02, 2011
doi:

Summary

This protocol describes a general procedure for studying recombinant receptor-binding domain (RBD)-based subunit vaccines against SARS. It includes methods for transfection and expression of RBD protein in 293T cells, immunization of mice with RBD and detection of neutralization activity of mouse sera using an established SARS pseudovirus neutralization assay.

Abstract

Based on their safety profile and ability to induce potent immune responses against infections, subunit vaccines have been used as candidates for a wide variety of pathogens 1-3. Since the mammalian cell system is capable of post-translational modification, thus forming properly folded and glycosylated proteins, recombinant proteins expressed in mammalian cells have shown the greatest potential to maintain high antigenicity and immunogenicity 4-6.

Although no new cases of SARS have been reported since 2004, future outbreaks are a constant threat; therefore, the development of vaccines against SARS-CoV is a prudent preventive step and should be carried out. The RBD of SARS-CoV S protein plays important roles in receptor binding and induction of specific neutralizing antibodies against virus infection 7-9. Therefore, in this protocol, we describe novel methods for developing a RBD-based subunit vaccine against SARS. Briefly, the recombinant RBD protein (rRBD) was expressed in culture supernatant of mammalian 293T cells to obtain a correctly folded protein with proper conformation and high immunogenicity 6. The transfection of the recombinant plasmid encoding RBD to the cells was then performed using a calcium phosphate transfection method 6,10 with some modifications. Compared with the lipid transfection method 11,12, this modified calcium phosphate transfection method is cheaper, easier to handle, and has the potential to reach high efficacy once a transfection complex with suitable size and shape is formed 13,14. Finally, a SARS pseudovirus neutralization assay was introduced in the protocol and used to detect the neutralizing activity of sera of mice vaccinated with rRBD protein. This assay is relatively safe, does not involve an infectious SARS-CoV, and can be performed without the requirement of a biosafety-3 laboratory 15.

The protocol described here can also be used to design and study recombinant subunit vaccines against other viruses with class I fusion proteins, for example, HIV, respiratory syncytial virus (RSV), Ebola virus, influenza virus, as well as Nipah and Handra viruses. In addition, the methods for generating a pseudovirus and subsequently establishing a pseudovirus neutralization assay can be applied to all these viruses.

Protocol

1. Recombinant SARS-CoV RBD Protein Preparation

  1. Prepare calcium phosphate transfection reagent
    1. 2X HBS buffer preparation: Mix together 16 g of NaCl, 0.4 g of Na2HPO4*7H2O, and 13.0 g of HEPES. Adjust pH to 7.00 and bring up total volume to 1000 mL in distilled water. After filtering the solution for sterilization, aliquot and store it at -20°C.
      Hint: Any variation of the pH value would affect the transfection results. Thus, it is advisable to test several pH values around 7.00 (for example, 6.99, 7.00, or 7.01) and find the best one for the transfection using the method introduced below.
    2. 2.5 M CaCl2 preparation: Add 73.5 g of CaCl2*2H2O to distilled water in a final volume of 200 mL. Filter the solution and store at -20°C.
  2. Recombinant plasmid transfection and protein purification
    1. Split 293T cells at 50-70% confluency 24 h before transfection. Grow cells in T-175 cm2 tissue culture flasks in 40 mL DMEM containing 10% heat-inactivated (HI) FBS and 1% Penicillin/Streptomycin (P/S) at 37°C in 5% CO2.
    2. All transfection reagents should be brought up to room temperature before transfection. These reagents include 2X HBS, 2.5M CaCl2, DiH2O, and rRBD plasmid 6.
      Hint: The final recombinant plasmid construct used for protein expression should contain a signal peptide to ensure secretion of expressed recombinant proteins to the culture supernatant. A 6x His tag may be added to the C-terminal of the expressed protein for easy purification.
    3. Prepare one 50 mL (A) and one 15 mL (B) BD Falcon tube, and add reagents to the tubes as indicated in Table 1. Add 2X HBS buffer to tube A. In tube B, add 2.5M CaCl2 and rRBD plasmid, and bring the volume to the requirement in DiH2O.
      A. One T-175 cm2 tissue culture flask (4000 μL/flask): prepare for rRBD expression
      Tube A Tube B
      2X HBS 2000 μL 2.5M CaCl2 200 μL
          rRBD plasmid DNA 40 μg
          DiH2O to 2000 μL
      B. One 100-mm petri dish (1000 μL/dish): prepare for SARS pseudovirus production
      Tube A Tube B
      2X HBS 500 μL 2.5M CaCl2 50 μL
          SARS-CoV S plasmid DNA 5 μg
          HIV-1 plasmid (pNL4-3.luc.RE) 5 μg
          DiH2O to 500 μL
      Table 1. Transfection mixture preparation and volumes
      The volumes listed in Table 1 are for one transfection unit. If more flasks or dishes are used for the transfection, adjust volumes accordingly.
    4. Add the DNA-calcium solution in tube B into tube A in a dropwise manner, while maintaining constant and gentle mixing in a vortex. Let the mixture sit at room temperature for 20-30 min. The key for successful calcium phosphate transfection depends on the size and shape of the precipitate formed. Thus, the mixture should be vortexed constantly and slowly to meet this requirement and, as a result, improve transfection efficacy.
    5. Add mixture in a dropwise and even manner into 293T cells (4000 μL/flask). Culture cells in incubator at 37°C in 5% CO2.
    6. Replace the culture medium with fresh serum-free OPTI-MEM I Reduced-Serum Medium (50 mL/flask) 8-10 h post-transfection. Continue to culture cells for two more days in the same condition.
    7. Collect supernatant containing expressed rRBD protein 72 h post-transfection. Centrifuge at 6000 rpm for 15 min to remove cell debris. Add protease inhibitor cocktail to the collected supernatant and store at 4°C overnight.
    8. On the next day, purify rRBD recombinant protein from the culture supernatant using Ni-NTA Superflow following manufacturer’s instructions.
    9. Concentrate purified protein using Amicon Ultra -15 concentration tubes. After protein concentration, add PBS to the concentration tubes and centrifuge again to remove imidazole in elution buffer. Calculate protein concentration and store purified protein at -80°C until use.

2. Mouse Immunization and Sample Collection

  1. Pre-warm Sigma adjuvant system (SAS) to 40-45°C according to manufacturer’s instructions. Add 1 mL PBS per vial and mix thoroughly.
  2. Prepare protein-adjuvant emulsion according to the protocol in Table 2. Pipette calculated rRBD protein into a 1.5 mL tube. Add equal volume of SAS adjuvant to the tube and vortex vigorously for 2-3 min to form emulsion.
    Hint: The volumes listed in Table 2 are for one mouse. Adjust volumes according to the actual mouse numbers used. For each group, mix together the proteins and adjuvant required for each vaccine. Always prepare one extra sample for the vaccination to ensure accuracy.
    Group 1st vaccine
    (200 μL/mouse)
    2nd vaccine
    (200 μL/mouse)
    3rd vaccine
    (200 μL/mouse)
    rRBD protein 20 μg protein in PBS
    (100 μL) + 100 μL SAS
    10 μg protein in PBS (100 μL) + 100 μL SAS 10 μg protein in PBS (100 μL) + 100 μL SAS
    PBS control 100 μL PBS +
    100 μL SAS
    100 μL PBS +
    100 μL SAS
    100 μL PBS +
    100 μL SAS
    Table 2. Mouse immunization protocol
  3. Subcutaneously prime-immunize female BALB/c mice (4-6 weeks old, 5 mice/group), and boost twice with rRBD and SAS as indicated in Table 2. Use PBS group as the control. The site for subcutaneous injections usually chosen is the loose skin between the shoulder blades. Alternatively, the ventral abdomen is commonly used, because it is easier to inject, and may observe any leakage from the injection sites. When repeated doses of vaccines are used, it is easy to select various injection sites, preventing potential local skin reactions.
  4. Bleed mice via retro-orbital with anesthetic before immunization and 10 days after each vaccination, and heat sera at 56°C for 30 min to inactivate complement. Store mouse sera at -20°C until use.

3. Neutralization Detection using Pseudovirus Neutralization Assay

  1. Prepare SARS pseudovirus
    1. Split 293T cells in 100 mm tissue culture petri dishes (2×106 cells/dish) 16 h before transfection, and grow cells as above.
    2. Prepare transfection reagents as indicated in Table 1. Co-transfect a plasmid encoding SARS-CoV S protein and a plasmid encoding Env-defective, luciferase-expressing HIV-1 genome (pNL4-3.luc.RE) using calcium phosphate transfection reagent.
    3. Replace medium with 10 mL fresh DMEM containing 10% FBS and 1% P/S 8-10 h post-transfection. Collect supernatant containing SARS pseudovirus 72 h post-transfection.
    4. Filter pseudovirus through a 0.45 μm filter. Aliquot and store at -80°C until use.
  2. SARS pseudovirus neutralization assay
    1. Split 293T cells expressing SARS-CoV receptor ACE2 (ACE2/293T) at 104 cells/100 μL/well in 96-well tissue culture plates 16 h before infection.
    2. Dilute SARS pseudovirus by 2-fold to detect the virus titer in ACE2/293T cells.
    3. Serially dilute mouse sera in 96-well tissue culture plates, and add equal volume of titrated SARS pseudovirus. Preincubate the plates at 37°C for 1 h.
    4. After incubation, add 100 μL of the sera-pseudovirus mixture to ACE2/293T cells, and continue to grow cells at 37°C in 5% CO2. Add fresh DMEM 24 h later.
    5. Completely remove culture supernatants from the plates 72 h post-infection. Add 1X luciferase cell culture lysis reagent (60 μL/well), and promote cell lysis with constant shaking of plates for 1-2 h at room temperature.
    6. Transfer cell lysates (50 μL/well) into luminometer plates (Microfluor 96-well plates). Add luciferase substrate (50 μL/well) included in luciferase assay system, and detect relative luciferase activity in Ultra 384 luminometer.
    7. Calculate SARS pseudovirus neutralization titer and present as 50% neutralizing antibody titer (NT50) 6.

Discussion

Cell density is an important factor affecting the efficacy of calcium phosphate-based transfection. In our experience, less than 70% confluency of the cells brings the best results. Thus, in order to improve transfection efficiency, it is recommended that cell density be kept at around 50-70% of confluency. The calcium phosphate transfection method is generally thought to be less efficient compared with other transfection methods, such as lipid transfection 16. However, in this protocol, we used a modified calcium phosphate transfection method whereby constant and slow mixing of the transfection solution in a vortex ensures the formation of a precipitate with the appropriate size and shape, thus improving transfection efficiency.

Divulgations

The authors have nothing to disclose.

Acknowledgements

This study was supported by the National Institutes of Health (NIH) of the United States (RO1 AI68002).

Materials

Material Name Type Company Catalogue Number Comment
NaCl   Sigma S7653  
Na2HPO4*7H2O   Sigma S2429  
HEPES   Sigma H3375  
CaCl2*2H2O   Sigma C5080  
DMEM   Invitrogen 12430  
HI FBS   Invitrogen 10438  
Penicillin/Streptomycin   Invitrogen 15140  
OPTI-MEM I Medium   Invitrogen 31985  
Protease inhibitor cocktail   Roche 11836170001  
Ni-NTA Superflow   Qiagen 30450  
Sigma adjuvant system   Sigma S6322  
Luciferase assay system   Promega E1501  
Luciferase cell culture lysis reagent (5X)   Promega E1531  
Amicon Ultra – 15   Millipore UFC901024  
Microfluor 96-well plates   Thermo Scientific 7905  
Ultra 384 luminometer   Tecan Systems    

References

  1. Pitcovski, J., Gutter, B., Gallili, G., Goldway, M., Perelman, B., Gross, G., Krispel, S., Barbakov, M., Michael, A. Development and large-scale use of recombinant VP2 vaccine for the prevention of infectious bursal disease of chickens. Vaccine. 21, 4736-4743 (2003).
  2. Tait, A., Hall, F. R. Theileria annulata: control measures, diagnosis and the potential use of subunit vaccines. Rev. Sci. Tech. 9, 387-403 (1990).
  3. Qi, Z., Zhou, L., Zhang, Q., Ren, L., Dai, R., Wu, B., Wang, T., Zhu, Z., Yang, Y., Cui, B., Wang, Z., Wang, H., Qiu, Y., Guo, Z., Yang, R., Wang, X. Comparison of mouse, guinea pig and rabbit models for evaluation of plague subunit vaccine F1+rV270. Vaccine. 28, 1655-1660 (2010).
  4. Rosser, M. P., Xia, W., Hartsell, S., McCaman, M., Zhu, Y., Wang, S., Harvey, S., Bringmann, P., Cobb, R. R. Transient transfection of CHO-K1-S using serum-free medium in suspension: a rapid mammalian protein expression system. Protein Expr. Purif. 40, 237-243 (2005).
  5. Du, L., Zhao, G., Li, L., He, Y., Zhou, Y., Zheng, B. J., Jiang, S. Antigenicity and immunogenicity of SARS-CoV S protein receptor-binding domain stably expressed in CHO cells. Biochem. Biophys. Res. Commun. 384, 486-490 (2009).
  6. Du, L., Zhao, G., Chan, C. C., Sun, S., Chen, M., Liu, Z., Guo, H., He, Y., Zhou, Y., Zheng, B. J., Jiang, S. Recombinant receptor-binding domain of SARS-CoV spike protein expressed in mammalian, insect and E. coli cells elicits potent neutralizing antibody and protective immunity. Virology. 393, 144-150 (2009).
  7. Ambrosino, D. M. Amino acids 270 to 510 of the severe acute respiratory syndrome coronavirus spike protein are required for interaction with receptor. J. Virol. 78, 4552-4560 (2004).
  8. Li, W., Moore, M. J., Vasilieva, N., Sui, J., Wong, S. K., Berne, M. A., Somasundaran, M., Sullivan, J. L., Luzuriaga, K., Greenough, T. C., Choe, H., Farzan, M. Angiotensin-converting enzyme 2 is a functional receptor for the SARS coronavirus. Nature. 426, 450-454 (2003).
  9. He, Y., Zhou, Y., Liu, S., Kou, Z., Li, W., Farzan, M., Jiang, S. Receptor-binding domain of SARS-CoV spike protein induces highly potent neutralizing antibodies: implication for developing subunit vaccine. Biochem. Biophys. Res. Commun. 324, 773-781 (2004).
  10. Batard, P., Jordan, M., Wurm, F. Transfer of high copy number plasmid into mammalian cells by calcium phosphate transfection. Gene. 270, 61-68 (2001).
  11. Pramfalk, C., Lanner, J., Andersson, M., Danielsson, E., Kaiser, C., Renstrom, I. M., Warolen, M., James, S. R. Insulin receptor activation and down-regulation by cationic lipid transfection reagents. BMC. Cell Biol. 5, 7-7 (2004).
  12. Rosser, M. P., Xia, W., Hartsell, S., McCaman, M., Zhu, Y., Wang, S., Harvey, S., Bringmann, P., Cobb, R. R. Transient transfection of CHO-K1-S using serum-free medium in suspension: a rapid mammalian protein expression system. Protein Expr. Purif. 40, 237-243 (2005).
  13. Jiang, M., Chen, G. High Ca2+-phosphate transfection efficiency in low-density neuronal cultures. Nat. Protoc. 1, 695-700 (2006).
  14. Jiang, M., Deng, L., Chen, G. High Ca(2+)-phosphate transfection efficiency enables single neuron gene analysis. Gene Ther. 11, 1303-1311 (2004).
  15. Han, D. P., Kim, H. G., Kim, Y. B., Poon, L. L., Cho, M. W. Development of a safe neutralization assay for SARS-CoV and characterization of S-glycoprotein. Virology. 326, 140-149 (2004).
  16. Toledo, J. R., Prieto, Y., Oramas, N., Sanchez, O. Polyethylenimine-based transfection method as a simple and effective way to produce recombinant lentiviral vectors. Appl. Biochem. Biotechnol. 157, 538-544 (2009).

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Du, L., Zhang, X., Liu, J., Jiang, S. Protocol for Recombinant RBD-based SARS Vaccines: Protein Preparation, Animal Vaccination and Neutralization Detection. J. Vis. Exp. (51), e2444, doi:10.3791/2444 (2011).

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