Introduction: Technological innovations have been instrumental in advancing vaccine design and protective benefit. Improvements in the safety, tolerability, and efficacy/effectiveness profiles have profoundly reduced vaccine-preventable global disease morbidity and mortality. Here we present an original vaccine platform, the Multiple Antigen Presenting System (MAPS), that relies on high-affinity interactions between a biotinylated polysaccharide (PS) and rhizavidin-fused pathogen-specific proteins. MAPS allows for flexible combinations of various PS and protein components.
Areas covered: This narrative review summarizes the underlying principles of MAPS and describes its applications for vaccine design against bacterial and viral pathogens in non-clinical and clinical settings.
Expert opinion: The utilization of high-affinity non-covalent biotin-rhizavidin interactions in MAPS allows for combining multiple PS and disease-specific protein antigens in a single vaccine. The modular design enables a simplified exchange of vaccine components. Published studies indicate that MAPS technology may support enhanced immunogenic breadth (covering more serotypes, inducing B- and T-cell responses) beyond that which may be elicited via PS- or protein-based conjugate vaccines. Importantly, a more detailed characterization of MAPS-based candidate vaccines is warranted, especially in clinical studies. It is anticipated that MAPS-based vaccines could be adapted and leveraged across numerous diseases of global public health importance.
Keywords: Bacterial vaccines; MAPS; biotin–rhizavidin interaction; cell-mediated immunity; glycocomplex; multiple antigen presenting system; pneumococcal vaccines; polysaccharide-specific antibodies.
Existing conjugate vaccines, consisting of pathogen-derived polysaccharides (PSs) and carrier proteins unrelated to the target pathogen, have helped to significantly reduce morbidity and mortality of several bacterial diseases. However, the worldwide burden of infectious diseases targeted by conjugate vaccines is still high. This is mainly due to high pathogen diversity and ongoing evolution, and innovative approaches are needed to respond to these challenges. Multiple Antigen Presenting System (MAPS) is an original vaccine technology that relies on strong molecular interactions between biotin and rhizavidin. MAPS is highly adaptable, as different PS and protein components can be precisely combined and easily exchanged, with limited damage to immunogenic epitopes (PS and protein features recognized by the immune system). Unlike existing conjugate vaccines, MAPS complexes contain pathogen-specific proteins, able to elicit broad immune responses directed against the pathogen. To date, investigational MAPS-based vaccines have been evaluated in several non-clinical studies; one candidate pneumococcal vaccine has been evaluated in early phase clinical studies in healthy children and adults (including older adults). In these clinical studies, the MAPS-based vaccine candidate was well tolerated and induced robust immune responses. If the favorable profile of MAPS-based vaccines is confirmed in further studies, these vaccines could be used against infectious diseases associated with significant morbidity and mortality.