Unconventional linkers facilitate potent stabilized coronavirus stem antibody responses following nanoparticle vaccination

Vaccine technologies that protect against a range of related pathogens within viral families, such as human immunodeficiency virus (HIV), influenza, and coronaviruses (CoVs) represent the future of viral vaccine development. Towards developing broad-spectrum CoV and influenza vaccines, we and others previously designed and evaluated CoV and influenza stem antigens; but these elicited relatively weak and sub-neutralizing antibody (Ab) responses. Multivalent antigen display on nanoparticles (NPs) is an established strategy to enhance and shape immunogenicity. However, one facet of NP vaccines has been largely overlooked: the indispensable linker segment between the antigen and NP core. Here, we introduce de novo –designed rigid (L2) and rarely used long flexible (L6) linkers to optimally display antigens on NPs, target occluded epitopes, and enhance cross-reactive Ab responses, using prefusion-stabilized Middle East respiratory syndrome coronavirus (MERS-CoV) spike (S-2P) and stem (SS) antigens as prototype antigens. Antigenic characterization of L2-NPs confirmed enhanced Ab binding and exposure of cross-reactive epitopes compared with L6-NPs and soluble antigens. Immunization with SS-L2-NPs elicited broader, more potent cross-reactive Ab responses across the seven human-infecting CoVs and pandemic threat WIV1-CoV, whereas SS-L6-NPs induced stronger neutralizing Ab responses against MERS-CoV, SARS-CoV-2, and WIV1-CoV. Ab competition and systems serology analyses revealed that SS-L2-NPs elicit robust Fc-mediated effector functions. By improving CoV-targeting Ab functionality, these linker approaches have the potential to confer broad-spectrum CoV protection and represent a promising strategy against hypervariable influenza and HIV viruses – as well as other broad viral families with pandemic potential.