The present invention provides, in some embodiments, methods, compositions, systems, and kits comprising nano-satellite complexes comprising: a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core; 3-25 satellite particles attached to, or absorbed to, said biocompatible coating; a plurality of antigenic peptides conjugated to, or absorbed to, said satellite particles; and at least one additional property. In other embodiments, provided herein are nano-satellite complexes comprising: a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core; a plurality of satellite particles attached to, or absorbed to, said biocompatible coating; a plurality of antigenic peptides conjugated to, or absorbed to, said satellite particles; and a plurality of LIGHT (TNFSF14) peptides conjugated to, or absorbed to, said satellite particles. In some embodiments, administration of the nanosatellite complexes to a subject with cancer achieves long-term cancer remission (e.g., when combined with an immune checkpoint inhibitor, such as αPD1).

The present invention provides a conjugate comprising: i) at least one first specific binding molecule which binds CD40, wherein said first specific binding molecule is an agonist of CD40; and ii) at least one second specific binding molecule which binds a tag moiety, wherein said tag moiety is not a cancer antigen, wherein said first specific binding molecule and second specific binding molecule are antigen-binding proteins comprising an antigen-binding domain of an antibody and are covalently linked. The conjugate can be combined with a tag construct comprising: i) a tag moiety which is not a cancer antigen; and ii) an antigen, being a cancer antigen or an antigen derived from a pathogen; wherein said antigen is a polypeptide and said tag moiety is covalently linked to said antigen, for use in therapy, to stimulate an immune response by a subject against the antigen in question.

The invention concerns a modified bacteria; a pharmaceutical composition comprising same; and a method of preventing or treating disease particularly, but not exclusively, cancer or an infectious disease using same.

The Rubella Virus Spike construct comprises at least one E1 component and one E2 component, which are linked together. The E1 component consists of the El envelope protein, whose C-terminal transmembrane region and intravirional domain are removed and whose N-terminus comprises the ectodomain of the El envelope protein. The E2 component consists of the E2 envelope protein whose transmembrane regions and intravirional domain removed and whose C-terminus comprising the ectodomain of the E2 envelope protein. The C-terminus of the E2 component is connected to the N-terminus of the E1 component by direct fusion or by means of a linker to form an E1-E2 fusion protein.

The invention describes kit of parts of polypeptides comprising: a) a peptide comprising: a1) an MHC class II T cell epitope or a CD1 d-restricted NKT cell epitope, and a2) immediately adjacent to said epitope or separated by at most 7 amino acids from said epitope a [CST]-X(2)-C [SEQ ID NO:7] or C-X(2)-[CST] [SEQ ID NO:8] oxidoreductase motif sequence, and b) a polypeptide comprising: b1) a therapeutic protein and b2) the epitope defined in a1), wherein the epitope sequence is a sequence which differs from the sequence of the protein of b1). The therapeutic protein, in combination with the peptide, is used to prevent an immune response against the therapeutic protein.

The present invention provides methods and compositions related to multivalent carbohydrate antigen structures comprising cancer or infection associated ganglioside carbohydrate antigens. Said carbohydrate structures may be used to induce immunity against said carbohydrate antigens. In some embodiments, carbohydrate structures may be administered to a subject thereby inducing immunity in the subject, for example, the administration of a vaccine comprising said carbohydrate structure. Also provided are methods to induce an immune response in a subject in need thereof by administering said carbohydrate structure. Further provided are methods of producing an antibody or TCR that bind said carbohydrate antigens.

The present disclosure provides T-cell modulatory multimeric polypeptides (TMMPs) comprising an autoimmune dis-ease-associated-associated peptide epitope, MHC class II polypeptides, and one or more immunomodulatory polypeptides. A TMMP of the present disclosure is useful for modulating activity of a T cell. Thus, the present disclosure provides compositions and methods for modulating the activity of T cells, as well as compositions and methods for treating persons who have an autoimmune disease.

The present disclosure is directed to individual peptide immunogen constructs targeting portions of the Tau protein for the treatment and/or prevention of tauopathies. The present disclosure is also directed to compositions containing the peptide immunogen constructs, methods of making and using the peptide immunogen constructs, and antibodies produced by the peptide immunogen constructs.

The present invention generally relates to a personalized cancer vaccine comprising a recombinant poxvirus encoding one or more neopeptide(s) or a composition comprising such a recombinant poxvirus and a pharmaceutically acceptable vehicle as well as the use of said personalized cancer vaccine for treating a cancerous subject in need thereof. A specific embodiment is directed to a method of providing such a vaccine or composition comprising an identification step comprising a) extracting the DNA from a tumor sample and a non-tumor sample, b) selecting target regions, c) sequencing said target regions from said extracted DNAs and d) identifying one or more tumor-specific mutation(s) by comparing the DNA sequences obtained from said tumor and non-tumor samples. Embodiments also include a method of treating cancer or preventing its relapse comprising administration of such a personalized cancer vaccine. The invention is of very special interest in the field of personalized immunotherapy.

The present invention provides compositions and methods for inducing an immune response in a subject in need thereof, comprising administering to the subject an immunologically-effective amount of a live Salmonella Typhi vector, wherein the Salmonella Typhi vector has been engineered to express one or more cancer antigens. In some aspects the vector has been engineered to express an outer membrane folding protein BamA or a fragment or variant thereof; and a lipid A deacylase PagL or a fragment or variant thereof, wherein the Salmonella Typhi vector is capable of delivering the antigen to a mucosal tissue or subcutaneously to dendritic cells via an outer membrane vesicle when administered to a subject.