The present embodiments provide for a Mycobacterium tuberculosis (M. tuberculosis) Multiple Antigen Presenting System (MAPS) immunogenic composition comprising an immunogenic polysaccharide which induces an immune response, where at least one M. tuberculosis 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 Mycobacterium tuberculosis, Type 5 (CP5) or Type 8 (CP8), or a combination of Type 5 or Type 8 capsular polysaccharide from Staphylococcus aureus, or alternatively, a different immunogenic capsular or noncapsular polysaccharide, and where the protein or peptide M. tuberculosis antigens are indirectly linked via an affinity binding pair. The present M. tuberculosis-MAPS immunogenic compositions can elicit both humoral and cellular immune responses to the immunogenic polysaccharide and one or multiple M. tuberculosis antigens at the same time.

The present invention relates to MHC-peptide complexes and uses thereof in the diagnosis of, treatment of or vaccination against a disease in an individual. More specifically the invention discloses MHC complexes comprising Mycobacterium tuberculosis antigenic peptides and uses there of.

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

The present invention relates to biofunctionalized nanoparticles and uses thereof in adoptive cell therapy. In particular, the present invention relates to a nanoparticle comprising an amount of at least one antigen and an amount of at least one antibody having specificity for a B cell receptor wherein the antigen and antibody are attached to the surface of the nanoparticle.

The disclosure provides modified biotin-binding proteins which can be expressed in soluble form in high yield in bacteria. Also provided are fusion proteins comprising the modified biotin-binding protein and an antigen. The disclosure further provides non-hemolytic variants of alpha-hemolysin from S. aureus and fusion protein comprising non-hemolytic variant of alpha-hemolysin and a biotin-binding domains. Immunogenic compositions comprising the proteins are also disclosed and use of such immunogenic compositions for inducing an immune response or for vaccinating a subject are also disclosed.

Provided herein are methods for transducing a plurality of cells in a composition of cells, such as a population of lymphocytes, containing viral particles. In some aspects, provided methods and reagents for the transduction of cell populations involve binding of agents to a molecule on the surface of the cells. In some cases, the reagents are multimerization reagents and the one or more agents are multimerized by reversibly binding to the reagent. In some aspects, the multimerized agent can provide for transduction and/or expansion or proliferation or other stimulation of a population of cells, and then such agents can be removed by disruption of the reversible bond. Also provided are compositions, apparatus and methods of use thereof.

Provided herein are oligomeric reagents, including oligomeric reagents of streptavidin or a streptavidin mutein, and compositions thereof and methods for manufacturing oligomeric reagents, including methods for reliably manufacturing oligomeric particle reagents of a desired size. In some cases, the reagents are oligomeric particle reagents containing a plurality of binding sites for agents, and thus the one or more agents are multimerized by reversibly binding to the oligomeric particle reagent, e.g., thereby creating a multimerized oligomeric particle reagent, having stimulatory agents multimerized thereon. Also provided are methods for using the oligomeric reagents for incubation or culturing, such as to induce stimulation of expansion (proliferation), activation, costimulation and/or survival, of a composition of cells such as a population of lymphocytes. In some aspects, the disclosure provides methods and reagents for the stimulation, e.g., of expansion (proliferation), survival or persistence, activation, costimulation, or other effect, of cell populations that involve binding of agents to a molecule on the surface of the cells, thereby providing one or more signals to the cells.

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 relates to extracellular vesicles (EVs), e.g., exosomes, which can be rapidly modified to comprise an antigen of interest, and the uses of such EVs as vaccines for the treatment of wide range of diseases or disorders. Also provided herein are methods for preparing and manufacturing such EVs for use as vaccines.

The disclosed bead vectors direct entry into a cell of monocytic origin and cause the expression of an extracellular domain of PD-1, an anti-CTLA4 antibody, or an antibody that is specific for a checkpoint protein. The bead vectors can comprise a nucleic acid component, a lysosome evading component and a bead particle that can be phagocytized. The disclosed vectors are useful in various methods of cancer therapy, treatment, and prevention. Due to the ability of monocytic cells to target tumors, the disclosed vectors are particularly well suited for use in anti-tumor applications and directing expression of target genes in tumor-associated macrophages.