Abstract
While biomaterials provide a platform to control the delivery of vaccines, the recently discovered intrinsic inflammatory characteristics of many polymeric carriers can also complicate rational design because the carrier itself can alter the response to other vaccine components. To address this challenge, we recently developed immune-polyelectrolyte multilayer (iPEMs) capsules electrostatically assembled entirely from peptide antigen and molecular adjuvants. Here, we use iPEMs built from SIINFEKL model antigen and polyIC, a stimulatory toll-like receptor agonist, to investigate the impact of pH on iPEM assembly, the processing and interactions of each iPEM component with primary immune cells, and the role of these interactions during antigen-specific T cell responses in coculture and mice. We discovered that iPEM assembly is pH dependent with respect to both the antigen and adjuvant component. Controlling the pH also allows tuning of the relative loading of SIINFEKL and polyIC in iPEM capsules. During in vitro studies with primary dendritic cells (DCs), iPEM capsules ensure that greater than 95% of cells containing at least one signal (i.e., antigen, adjuvant) also contained the other signal. This codelivery leads to DC maturation and SIINFEKL presentation via the MHC-I antigen presentation pathway, resulting in antigen-specific T cell proliferation and pro-inflammatory cytokine secretion. In mice, iPEM capsules potently expand antigen-specific T cells compared with equivalent admixed formulations. Of note, these enhancements become more pronounced with successive booster injections, suggesting that iPEMs functionally improve memory recall response. Together our results reveal some of the features that can be tuned to modulate the properties of iPEM capsules, and how these modular vaccine structures can be used to enhance interactions with immune cells in vitro and in mice.
Highlights
Self-assembled biomaterials offer many features that can be exploited to enhance vaccination
We recently reported the design of immune-polyelectrolyte multilayers composed entirely of model peptide antigen (SIINFEKL) and polycytidylic acid (polyIC) (TLR3 agonist) as an adjuvant.[1,29]
To develop insight into the physicochemical and immunological function of immune-polyelectrolyte multilayers (iPEMs), here we studied the impact of assembly conditions on iPEM growth and cargo levels, used these materials to assess codelivery of the antigens and adjuvants comprising the iPEMs into primary dendritic cells (DCs)
Summary
Self-assembled biomaterials offer many features that can be exploited to enhance vaccination Some of these capabilities include codelivery, controlled release, and encapsulation or condensation of antigens or molecular adjuvants into particulate forms that more efficiently trigger pathogen-sensing pathways that promote adaptive immunity.[1−3] One important class of such pathways are toll-like receptors (TLRs). Because CpG, polyIC, and other TLR agonists are recognized in a pattern-specific manner, these ligands offer more targeted strategies for directing activation of specific immune pathways during vaccination
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