A cGAMP-containing hydrogel for prolonged SARS-CoV-2 RBD subunit vaccine exposure induces a broad and potent humoral response

The receptor binding domain (RBD) of the SARS-CoV-2 virus spike protein has emerged as a promising target for generation of neutralizing antibodies. Although the RBD subunit is more stable than its encoding mRNA, RBD-based subunit vaccines have been hampered by RBD’s poor immunogenicity. We hypothesize that this limitation can be overcome by sustained co-administration with a more potent and optimized adjuvant than standard adjuvants. The endogenous innate immune second messenger, cGAMP, holds promise as potent activator of the anti-viral STING pathway. Unfortunately, delivery of cGAMP as a therapeutic exhibits poor performance due to poor pharmacokinetics and pharmacodynamics from rapid excretion and degradation by its hydrolase ENPP1. To overcome these limitations, we sought to create an artificial immunological niche enabling slow release of cGAMP and RBD to mimic natural infections in which immune activating molecules are co-localized with antigen. Specifically, we co-encapsulated cGAMP and RBD in an injectable polymer-nanoparticle (PNP) hydrogel. This cGAMP-adjuvanted hydrogel vaccine elicited more potent, durable, and broad antibody responses with improved neutralization as compared to dose-matched bolus controls and hydrogel-based vaccines lacking cGAMP. The cGAMP-adjuvanted hydrogel platform developed is suitable for delivery of other antigens and may provide enhanced immunity against a broad range of pathogens.