Engineering a Novel Bacterial Encapsulin for Programmable Surface Functionalization: From Single-Target to Mosaic Nanovaccines

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Abstract

Encapsulins are prokaryotic self-assembling protein nanocages with promise as nanovaccine scaffolds. Their utility as modular platforms require tolerance to surface engineering, high-yield soluble production, formulation stability, and controlled antigen (co-)display. Herein, a previously uncharacterized encapsulin from Alkaliphilus metalliredigens is engineered into a SpyCatcher-decorated nanoscaffold (Am-S) that enables controlled surface display of SpyTagged antigens. Cryo-EM confirms that the native encapsulin forms a T = 1 icosahedral nanocage, and that C-terminal SpyCatcher fusion yields Am-S without compromising nanocage assembly, symmetry, or structural integrity. Notably, Am-S exhibits high-yield soluble production in Escherichia coli , remains monodisperse after freeze–thaw and extended storage, and supports efficient SpyTagged peptide conjugation for single- and multi-antigen display. As a proof-of-concept, Am-S is functionalized with Alzheimer’s disease-associated amyloid-β and/or hyperphosphorylated tau epitopes to generate single-target nanocages displaying either antigen and dual-target mosaic nanocages co-displaying both. In mice, Am-S antigen display enhances antigen-specific IgG responses relative to free antigens and induces predominantly IgG1-biased humoral immunity. Mosaic nanocages elicit antibodies against both targets, with immune sera selectively recognizing amyloid-β- and phosphorylated tau-associated pathology in ex vivo brain sections from Alzheimer’s disease mouse models. These findings position Am-S as a manufacturable scaffold for developing multi-targeting nanovaccines against complex diseases.

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