Potent Bacterial Vaccines Require FcγRIIB-mediated Pathogen Capture by Liver Sinusoidal Endothelium

Abstract

ABSTRACTCertain vaccines are more effective than others against microbial infections, but the molecular mechanisms separating the two types of vaccines are largely undefined. Here, by comparing two vaccines ofStreptococcus pneumoniaewith identical antigens but different efficacies (pneumococcal conjugate vaccine – PCV13 and pneumococcal polysaccharide vaccine – PPV23), we reveal that superior vaccine protection against blood-borne bacteria is primarily achieved by activating pathogen capture of the sinusoidal endothelial cells (ECs) in the liver. Consistent with its superior protection in humans, PCV13 confers a more potent protection than PPV23 against pneumococcal infection in mice.In vivoreal-time imaging and genetic mutagenesis revealed that PCV13 activates both liver ECs and resident macrophages Kupffer cells (KCs) to capture IgG-coated bacteria via IgG Fc gamma receptor (FcγR). In particular, the FcγRIIB-mediated capture by ECs is responsible for PCV13-induced superior protection. In contrast, PPV23 only activates KCs (but not ECs) to achieve a less effective pathogen capture and protection through complement receptor-mediated recognition of IgM- and C3-coated bacteria. These liver-based vaccine protection mechanisms are also found with the vaccines ofNeisseria meningitidisandKlebsiella pneumoniae, another two important invasive human pathogens. Our findings have uncovered a novel EC- and FcγRIIB-mediated mechanism in the liver for more efficacious vaccine protection. These findings can serve asin vivofunctional readouts to evaluate vaccine efficacy and guide the future vaccine development.One Sentence SummaryVaccine efficacy is defined by FcγRIIB-mediated capture of antibody-coated bacteria via liver sinusoidal endothelial cells.