Disclosed are immunotherapeutic compositions and the concurrent use of combinations of such compositions for the improved induction of therapeutic immune responses and/or for the prevention, amelioration and/or treatment of disease, including, but not limited to, cancer and infectious disease.

Provided are polynucleotides and viral vectors, particularly, alphavirus vectors such as Sindbis viral vectors, which encode multiple, e.g., two or more, epitopes of at least one tumor associated antigen in which each epitope is separated by a processing or enzyme cleavage site. The multiple epitopes of the two or more tumor associated antigens encoded by the described polynucleotides and viral vectors may be the same or different. Methods of treating mammalian subjects having a cancer or tumor expressing the tumor associated antigen epitopes are provided, in which the viral vectors encoding the multiple epitopes, as well as other immunostimulatory or immunomodulatory components, generate an anti-cancer or anti-tumor immune response in which high levels of effector T cells increase the survivability of tumored mammalian subjects and result in epitope spreading, thus providing a further enhancement of the immune response.

A set of target peptides are presented by HLA A*0101, A*0201, A*0301, B*4402, B*2705, B*1402, and B*0702 on the surface of disease cells. They are envisioned to among other things (a) stimulate an immune response to the proliferative disease, e.g., cancer, (b) to function as immunotherapeutics in adoptive T cell therapy or as a vaccine, (c) facilitate antibody recognition of tumor boundaries in surgical pathology samples, (d) act as biomarkers for early detection and/or diagnosis of the disease, and (e) act as targets in the generation antibody-like molecules which recognize the target-peptide/MHC complex.

The present invention provides compositions and systems for delivery of nanocarriers to cells of the immune system. The invention provides vaccine nanocarriers capable of stimulating an immune response in T cells and/or in B cells, in some embodiments, comprising at least one immunomodulatory agent, and optionally comprising at least one targeting moiety and optionally at least one immunostimulatory agent. The invention provides pharmaceutical compositions comprising inventive vaccine nanocarriers. The present invention provides methods of designing, manufacturing, and using inventive vaccine nanocarriers and pharmaceutical compositions thereof. The invention provides methods of prophylaxis and/or treatment of diseases, disorders, and conditions comprising administering at least one inventive vaccine nanocarrier to a subject in need thereof.

The present invention is directed to a pharmaceutical composition including (e.g. for use as an adjuvant) a polymeric carrier cargo complex, comprising as a carrier a polymeric carrier formed by disulfide-crosslinked cationic components; and as a cargo at least one nucleic acid molecule, and at least one antigen that is selected from an antigen from a pathogen associated with infectious disease; an antigen associated with allergy or allergic disease; an antigen associated with autoimmune disease; or an antigen associated with a cancer or tumour disease, or in each case a fragment, variant and/or derivative of said antigen. The pharmaceutical composition allows for efficient induction of an adaptive immune response directed against said antigen. The present invention furthermore provides kits, as well as the use of the pharmaceutical composition or the kit as a vaccine, particularly in the treatment of infectious diseases, allergies, autoimmune diseases and tumour or cancer diseases.

The present disclosure provides an allogeneic whole cell cancer vaccine platform that includes compositions and methods for treating and preventing cancer. Provided herein are compositions containing a therapeutically effective amount of cells from one or more cancer cell lines, some or all of which are modified to (i) inhibit or reduce expression of one or more immunosuppressive factors by the cells, and/or (ii) express or increase expression of one or more immunostimulatory factors by the cells, and/or (iii) express or increase expression of one or more tumor-associated antigens (TAAs), including TAAs that have been mutated, and which comprise cancer cell lines that natively express a heterogeneity of tumor associated antigens and/or neoantigens, and/or (iv) express one or more tumor fitness advantage mutations, including but not limited to acquired tyrosine kinase inhibitor (TKI) resistance mutations, EGFR activating mutations, and/or (v) express modified ALK intracellular domain(s), and/or express one or more driver mutations. Also provided herein are methods of making and preparing the vaccine compositions and methods of use thereof.

Disclosed are methods of producing poxvirus-based vectors or recombinant poxvirus-based vectors from naturally derived, chemically synthesized DNA fragments, or a combination of naturally derived and chemically synthesized DNA fragments. One or more DNA sequences encoding one or more antigens, subunits or fragments thereof or other heterologous gene sequences are inserted in one or more poxvirus insertion sites in one or more DNA fragments. The methods include transfecting a host cell with one or more circular or linear DNA fragments such that a poxvirus or recombinant poxvirus is reconstituted in the host cell, the reconstituted poxvirus or recombinant poxvirus comprising the genome of a desired poxvirus. Also disclosed are poxviruses or recombinant poxviruses produced by the technology and uses thereof.

The present invention relates generally to the identification of tumor specific neo open-reading-frame peptides (NOPs) and the uses of these NOPs to produce cancer vaccines and the like. More in particular the invention relates to identifying at least one neoantigen in a patient and based thereupon preparing a subject-specific immunogenic composition. With the present invention it becomes possible to provide off-the-shelf cancer vaccines and the like within a short period of time and for potentially 30% of the total population of patients suffering from cancer.

The disclosure provides, inter alia, methods and materials involved in treating cancer using a p53 vaccine in combination with a PD-1 pathway inhibitor.

The disclosure provides, inter alia, methods and materials involved in treating cancer using a p53 vaccine in combination with a PD-1 pathway inhibitor.