1. Experimental and in silico evidence suggests vaccines are unlikely to be affected by D614G mutation in SARS-CoV-2 spike protein
- Author
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Mary Tachedjian, Gough G. Au, Trevor W. Drew, Sarah Edwards, Trevor R.F. Smith, Kim R. Blasdell, Sue Lowther, Rachel Layton, Matthew P. Bruce, Julian Druce, Alexander J. McAuley, Seshadri S. Vasan, Michael J. Kuiper, Timothy Poole, Glenn A. Marsh, Sarah Jane Riddell, Jennifer A. Barr, Peter A. Durr, Shawn Todd, and Kate E. Broderick
- Subjects
lcsh:Immunologic diseases. Allergy ,0301 basic medicine ,Proteases ,In silico ,Immunology ,Biology ,Brief Communication ,lcsh:RC254-282 ,Virus ,Neutralization ,03 medical and health sciences ,chemistry.chemical_compound ,0302 clinical medicine ,RNA polymerase ,Pharmacology (medical) ,030212 general & internal medicine ,Viral evolution ,chemistry.chemical_classification ,Pharmacology ,Vaccines ,SARS-CoV-2 ,Elastase ,lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens ,Virology ,030104 developmental biology ,Infectious Diseases ,chemistry ,lcsh:RC581-607 ,Glycoprotein - Abstract
The ‘D614G’ mutation (Aspartate-to-Glycine change at position 614) of the SARS-CoV-2 spike protein has been speculated to adversely affect the efficacy of most vaccines and countermeasures that target this glycoprotein, necessitating frequent vaccine matching. Virus neutralisation assays were performed using sera from ferrets which received two doses of the INO-4800 COVID-19 vaccine, and Australian virus isolates (VIC01, SA01 and VIC31) which either possess or lack this mutation but are otherwise comparable. Through this approach, supported by biomolecular modelling of this mutation and the commonly-associated P314L mutation in the RNA-dependent RNA polymerase, we have shown that there is no experimental evidence to support this speculation. We additionally demonstrate that the putative elastase cleavage site introduced by the D614G mutation is unlikely to be accessible to proteases.
- Published
- 2020