The present embodiments provide for an S. aureus (SA) Multiple Antigen Presenting System (MAPS) immunogenic composition comprising an immunogenic polysaccharide which induces an immune response, where at least one S. aureus (SA) peptide or polypeptide antigen is associated to the immunogenic polysaccharide by complementary affinity molecules. In some embodiments, the immunogenic polysaccharide can be an antigenic capsular polysaccharide of a Type 5 or Type 8 from S. aureus, or alternatively, a different immunogenic capsular or noncapsular polysaccharide, and where the protein or peptide SA antigens are indirectly linked via an affinity binding pair. The present SA-MAPS immunogenic compositions can elicit both humoral and cellular immune responses to the immunogenic polysaccharide and one or multiple SA antigens at the same time.

The present invention provides HIV-1 vaccine immunogens. Some of the immunogens contain a soluble gp140-derived protein that harbors a modified N-terminus of the HR1 region in gp41. Some of the immunogens contain an HIV-1 Env-derived trimer protein that is presented on a nanoparticle platform. The invention also provides methods of using the HIV-1 vaccine immunogens for eliciting an immune response or treating HIV infections.

The present invention is directed to novel heterologous promiscuous and artificial T helper cell epitopes (Th epitopes) designed to provide optimum immunogenicity of a target antigenic site. The disclosed Th epitopes, when covalently linked to a B cell epitope in a peptide immunogen construct, elicit a strong antibody response to the B cell epitope of the target antigenic site. The Th epitopes are immunosilent on their own, i.e., little, if any, of the antibodies generated by the peptide immunogen constructs will be directed towards the Th epitope, thus allowing a very focused immune response directed to the targeted antigenic site. The heterologous promiscuous Th epitopes provide effective and safe peptide immunogens that do not generate inflammatory, anti-self, cell-mediated immune responses following administration.

The present invention relates to new glycoconjugates comprising Streptococcus pneumoniae capsular saccharide antigens and uses thereof. Glycoconjugates of the present invention will typically comprise 2 or more saccharides antigens conjugated to the same molecule of the protein carrier. The invention also relates to vaccination of human subjects, in particular infants and elderly, against pneumoccocal infections using immunogenic compositions comprising said novel glycoconjugates.

Embodiments of immunogenic conjugates including the HIV-1 Env fusion peptide and methods of their use and production are disclosed. In several embodiments, the immunogenic conjugates can be used to generate an immune response to HIV-1 Env in a subject, for example, to treat or prevent an HIV-1 infection in the subject.

The present disclosure provides (a) vectors comprising a multi-antigen construct encoding two, three, or more immunogenic PAA polypeptides; (b) compositions comprising the vectors, (c) methods relating to uses of the vectors and compositions for eliciting an immune response or for treating prostate cancers.

Bivalent immunogenic compositions against anthrax and plague are disclosed herein. One bivalent immunogenic composition comprises a triple fusion protein containing three antigens, F1 and V from Yersinia pestis and PA antigen from Bacillus anthracis fused in-frame and retaining structural and functional integrity of all three antigens. Another bivalent immunogenic composition comprises bacteriophage nanoparticles arrayed with these three antigens on the capsid surface of the bacteriophage nanoparticles. These bivalent immunogenic compositions are able to elicit robust immune response in a subject administered said the bivalent immunogenic compositions and provide protection to the subject against sequential or simultaneous challenge with both anthrax and plague pathogens.

Conjugates of synthetic nanocarriers, complexed with syngeneic (self) proteins adducted with haptens or other poorly immunogenic antigens (antigens of low immunogenicity), elicit selective humoral responses or antibodies against the hapten or antigen and not to self-protein. Compositions include these conjugates, which can be used as vaccines. Methods of making and using them are described herein. In a typical embodiment, a conjugate including a hapten or antigen of low immunogenicity associated with a particular disease (e.g., infection, cancer) can be used as a vaccine by eliciting antibodies that specifically neutralize the hapten or antigen. These hapten (and other poorly immunogenic antigen)-carrying nanocarriers selectively target antigen presenting cells resulting in a strong anti-hapten humoral response, and thus find use in vaccines for cancer (e.g., cancers of lung, cervix, breast, brain, liver pancreas, ovaries, skin, etc.), infectious diseases and inflammatory-mediated diseases, as well as for autoimmune disorders.

Compositions and methods for modified dendrimer nanoparticle (“MDNP”) delivery of therapeutic, prophylactic and/or diagnostic agent such as large repRNA molecules to the cells of a subject have been developed. MDNPs efficiently drive proliferation of antigen-specific T cells against intracellular antigen, and potentiate antigen-specific antibody responses. MDNPs can be multiplexed to deliver two or more different repRNAs to modify expression kinetics of encoded antigens and to simultaneous deliver repRNAs and mRNAs including the same UTR elements that promote expression of encoded antigens.

The present disclosure provides polypeptides, and nucleic acids encoding the polypeptides, that include severe acute respiratory syndrome Co-V-2 (SARS-CoV-2) spike polypeptide receptor-binding domain (RBD) polypeptides or variants thereof, which are capable of multimerization and thus presenting multiple copies of the RBD to enhance the immune response generated when the polypeptide is administered to a subject. The disclosure also provides multimers, scaffolds, compositions, pharmaceutical compositions, and vaccines that include the polypeptides and/or nucleic acids that encode such polypeptides.