Version 3 2021-04-08, 12:03Version 3 2021-04-08, 12:03
Version 2 2021-04-01, 23:53Version 2 2021-04-01, 23:53
Version 1 2021-04-01, 10:18Version 1 2021-04-01, 10:18
journal contribution
posted on 2021-04-08, 12:03authored byJuliane Brun, Snežana Vasiljevic, Bevin Gangadharan, Mario Hensen, Anu V. Chandran, Michelle L. Hill, J.L. Kiappes, Raymond A. Dwek, Dominic S. Alonzi, Weston B. Struwe, Nicole Zitzmann
Severe acute respiratory
syndrome coronavirus 2 is the causative
pathogen of the COVID-19 pandemic which as of March 29, 2021, has
claimed 2 776 175 lives worldwide. Vaccine development
efforts focus on the viral trimeric spike glycoprotein as the main
target of the humoral immune response. Viral spikes carry glycans
that facilitate immune evasion by shielding specific protein epitopes
from antibody neutralization, and antigen efficacy is influenced by
spike glycoprotein production in vivo. Therefore, immunogen integrity
is important for glycoprotein-based vaccine candidates. Here, we show
how site-specific glycosylation differs between virus-derived spikes,
wild-type, non-stabilized spikes expressed from a plasmid with a CMV
promoter and tPA signal sequence, and commonly used recombinant, engineered
spike glycoproteins. Furthermore, we show that their distinctive cellular
secretion pathways result in different protein glycosylation and secretion
patterns, including shedding of spike monomeric subunits for the non-stabilized
wild-type spike tested, which may have implications for the resulting
immune response and vaccine design.