The present invention provides improved LAMP Constructs comprising specific fragments of the LAMP lumenal domain to deliver cancer antigens to immune cells for enhanced processing. These LAMP Constructs can be used for the treatment of disease and in particular hyperproliferative disorders and/or cancer. The improved LAMP Constructs allow for presentation of properly configured three dimensional epitopes for production of an immune response when administered to a subject. The improved LAMP Constructs can be multivalent molecules, and/or can be provided as part of a multivalent vaccine containing two or more LAMP Constructs. The improved LAMP Constructs as described herein can also be used to generate antibodies when administered to a non-human vertebrate.

Embodiments of the invention are directed to fibrillar adjuvants. Epitopes assembled into nanofibers by a short synthetic fibrillization domain elicited high antibody titers in the absence of any adjuvant.

Disclosed herein are vaccine compositions, in particular, polyvalent icosahedral compositions for antigen presentation. The disclosed compositions may contain an S particle made up of recombinant fusion proteins. The recombinant fusion proteins may include a norovirus (NoV) S domain protein, a linker protein domain operatively connected to the norovirus S domain protein, and an antigen protein domain operatively connected to said linker.

The present disclosure relates to novel peptide-based vaccines, methods of manufacturing the novel peptide-based vaccines and uses thereof for delivering peptide antigens to induce an immune response, and in particular a T cell response to a subject.

Disclosed is an immunogen comprising a fusion protein, wherein the fusion protein comprises a Zika virus (ZIKV) envelope protein, optionally a signal peptide, and a multimerization domain. The signal peptide is a premembrane (prM) signal peptide, an IgG signal peptide, or a human secretory signal peptide hidden Markov model, and the multimerization domain is an immunoglobulin Fc domain, a T4 fibritin foldon trimerization domain, or a human collagen XV trimerization domain. Nucleic acids, vectors, and microneedle arrays including these compositions are disclosed. Methods of producing an immune response to ZIKV are also disclosed.

Provided are polypeptides and compositions comprising novel HSP-binding peptides. Such polypeptides and compositions are particularly useful as immunotherapeutics (e.g., cancer vaccines). Also provided are methods of inducing a cellular immune response using such polypeptides and compositions, methods of treating a disease using such polypeptides and compositions, kits comprising such polypeptides and compositions, and methods of making such compositions.

The present invention is directed towards an artificial RNA nanostructure comprising multiple external strands of RNA, each external strand comprising about 40-50 nucleotides; one internal strand of RNA comprising more than about 50 nucleotides; the internal strands and external strands assembled to form a triangle nanostructure, a square nanostructure, or a polygon nanostructure and a pRNA three-way junction (3WJ) motif at each vertex of the nanostructure. Such nanostructure can be provided in a composition together with an adjuvant for use in inducing the production of high affinity neutralizing antibodies or inhibitory antibodies, inducing the production of cytokines, inducing an immune response in a subject, or a combination thereof.

Provided herein are immunogenic compositions comprising a recombinant modified vaccinia virus Ankara (MVA) comprising a nucleic acid sequence encoding a flagellin, and a nucleic acid sequence encoding a heterologous disease-associated antigen, wherein the immunogenic composition induces increased T-cell and antibody mediated immune responses specific for the heterologous disease-associated antigen when administered to a subject, e.g. a human subject, and related methods and uses.

This disclosure provides nano-scale Artificial Antigen Presenting Cells (aAPC), which deliver stimulatory signals to lymphocytes, including T-helper lymphocytes, for use as a powerful tool for immunotherapy.

The present disclosure provides T cell modulatory polypeptides (T-Cell-MPs) comprising a chemical conjugation site at which a KRAS epitope has been conjugated and at least one immunomodulatory polypeptide sequence that may be selected to exhibit reduced binding affinity to its cognate co-immunomodulatory polypeptide. The T-Cell-epitope conjugates are useful for modulating (e.g., increasing proliferation or cytotoxic activity) the activity of T cells specific to the conjugate epitope, and accordingly for use as therapeutics. The T-Cell-epitope conjugates find use in treating a variety of cancers associated with KRAS.