RESUMO
The spike (S) glycoprotein of SARS CoV-2 is the target of neutralizing antibodies (NAbs) that are crucial for vaccine effectiveness. The S1 subunit binds ACE2 while the S2 subunit mediates virus-cell membrane fusion. S2 is a class I fusion glycoprotein and contains a central coiled coil that acts as a scaffold for the conformational changes associated with fusion function. The coiled coil of S2 is unusual in that the 3-4 repeat of inward-facing positions are mostly occupied by polar residues that mediate few inter-helical contacts in the prefusion trimer. We examined how insertion of bulkier hydrophobic residues (Val, Leu, Ile, Phe) to fill a cavity formed by Ala1016 and Ala1020 that form part of the 3-4 repeat affects the stability and antigenicity of S trimers. Substitution of Ala1016 with bulkier hydrophobic residues in the context of a prefusion-stabilized S trimer, S2P-FHA, was associated with increased thermal stability. The trimer stabilizing effects of filling the Ala1016/Ala1020 cavity was linked to improved S glycoprotein membrane fusion function. When assessed as immunogens, two thermostable S2P-FHA mutants derived from the ancestral isolate, A1016L (16L) and A1016V/A1020I (VI) elicited very high titers of neutralizing antibodies to ancestral and Delta-derived viruses (1/2,700-1/5,110), while neutralization titer was somewhat reduced with Omicron BA.1 (1/210-1,1744). The antigens elicited antibody specificities that could compete with ACE2-Fc for binding to the receptor-binding motif (RBM) and NAbs directed to key neutralization epitopes within the receptor-binding domain (RBD), N-terminal domain (NTD) and stem region of S2. The VI mutation enabled the production of intrinsically stable Omicron BA.1 and Omicron BA.4/5 S ectodomain trimers in the absence of an external trimerization motif (T4 foldon). The VI mutation represents a method for producing an intrinsically stable trimeric S ectodomain glycoprotein vaccine in the absence of a foreign trimerization tag. AUTHOR SUMMARYFirst-generation SARS CoV-2 vaccines that generate immune responses to ancestral Spike glycoprotein sequences have averted at least 14.4 million deaths, but their effectiveness against the recently emerged Omicron lineages is reduced. The updating of booster vaccines with variant Spike sequences are therefore likely required to maintain immunity as the pandemic continues to evolve. The Spike is a trimeric integral membrane protein with a membrane spanning sequence at its C-terminus. The Spike protein-based vaccine that is currently licensed for human use is produced by a complex process that reconstitutes the Spike in an artificial membrane. Alternatively, production of the Spike trimer as a soluble protein generally requires replacement of the membrane spanning sequence with a foreign often highly immunogenic trimerization motif that can complicate clinical advancement. We used systematic structure-directed mutagenesis coupled with functional studies to identify an alternative stabilization approach that negates the requirement for an external trimerization motif or membrane-spanning sequence. The replacement of 2 alanine residues that form a cavity in the core of the Spike trimer with bulkier hydrophobic residues resulted in increased Spike thermal stability. Thermostable Spike mutants retained major conserved neutralizing antibody epitopes and the ability to elicit broad and potent neutralizing antibody responses. One such mutation, referred to as VI, enabled the production of intrinsically stable Omicron variant Spike ectodomain trimers in the absence of an external trimerization motif. The VI mutation potentially enables a simplified method for producing a stable trimeric S ectodomain glycoprotein vaccine.
