Aspects of the disclosure relate to nucleic acid vaccines. The vaccines include one or more RNA polynucleotides having an open reading frame encoding one or more Chikungunya antigen(s), one or more Zika virus antigens, and one or more Dengue antigens. Methods for preparing and using such vaccines are also described.

The present invention relates to a vaccine composition which is form neutering or spaying an animal and comprises a recombinant protein in which cholera toxin B subunit (CTB) and gonadotropin-releasing hormone (GnRH) are fused. More specifically, provided are: a recombinant protein for neutering or spaying an animal and for inducing antibodies against GnRH; a recombinant vector for producing the recombinant protein; a vaccine composition for neutering or spaying an animal, the vaccine composition comprising the recombinant protein; and a method for neutering or spaying an animal by using the vaccine composition. The vaccine composition according to the present invention induces antibodies against GnRH in an individual, thereby atrophying the ovaries or testes thereof. Therefore, the present invention can, at low cost, a high level of safety, and with minimal side effects, replace surgical procedures for neutering and spaying, and be beneficially used to neuter or spay an animal.

Modified alphaviruses encoding a SARS-CoV-2 spike protein or antigenic segment of the SARS-CoV-2 spike protein are provided. The modified alphaviruses include replicative defective Sindbis viruses. The modified viruses express or are administered with an immunomodulatory agent that is an agonist antibody or antigenbinding fragment thereof, or a cytokine, or a combination thereof. Pharmaceutical compositions that include the modified alphaviruses and methods of using the modified alphaviruses and compositions that contain them are provided. The compositions are used to stimulate a therapeutic or protective effect against SARS-CoV-2 infection that includes humoral and cell mediated responses.

Disclosed herein are methods of forming compounds and exemplary compounds in the nature of a conjugated compound, which in some embodiments comprises an antigen and virus particle mixed in a conjugation reaction to form a conjugate mixture, such that the conditions and steps of forming these products allow for use of the conjugate mixture as a vaccine, including but not limited to use as a vaccine against various pathogens including for treatment of diseases caused by novel coronaviruses (including SARS-COV 2).

A peptide vaccine complexed so that the peptide vaccine can be delivered specifically to the surface of specific immune cells and a method for delivering a peptide vaccine specifically to the surface of specific immune cells. The peptide vaccine is combined with an IgG binding peptide capable of binding to an IgG that is an agonist against molecules on the surface of specific immune cells such as dendritic cells.

Disclosed herein are methods of forming compounds and exemplary stable compounds in the nature of a conjugated compound at refrigerated or room temperature, which in some embodiments comprises an antigen and virus particle mixed in a conjugation reaction to form a conjugate mixture, such that the conditions and steps of forming these products allow for use of the conjugate mixture as a vaccine, including but not limited to use as a vaccine against various pathogens including for treatment of diseases caused by novel coronaviruses (including SARS-COV 2).

The present invention relates to the construction and application of a fusion protein vaccine platform. The present invention provides a vaccine, comprising a fusion protein containing an interferon-target antigen-immunoglobulin Fc region (or antibody) and a Th cell helper epitope. The present invention also relates to use of a fusion protein containing an interferon-target antigen-immunoglobulin Fc region (or antibody) and a Th cell helper epitope in the preparation of prophylactic or therapeutic compositions. The vaccine of the present invention can be produced by eukaryotic cell expression systems to prepare wild-type and various mutant antigen vaccines, and vaccination by means of subcutaneous/muscular or nasal or other routes can lead to a strong immune response to a body. The vaccine of the present invention can be used as a prophylactic or therapeutic vaccine.

The present invention provides cell-targeting molecules which can deliver a CD8+ T-cell epitope cargo to the MHC class I presentation pathway of the cell. The cell-targeting molecules of the invention can be used to deliver virtually any CD8+ T-cell epitope from an extracellular space to the MHC class I pathway of a target cell, which may be a malignant cell and/or non-immune cell. The target cell can then display on a cell-surface the delivered CD8+ T-cell epitope complexed with MHC I molecule. The cell-targeting molecules of the invention have uses which include the targeted labeling and/or killing of specific cell-types within a mixture of cell-types, including within a chordate, as well as the stimulation of beneficial immune responses. The cell-targeting molecules of the invention have uses, e.g., in the treatment of a variety of diseases, disorders, and conditions, including cancers, tumors, growth abnormalities, immune disorders, and microbial infections.

The disclosure provides novel antigen-binding proteins that bind STEAP1 and methods of use.

The present invention relates to an anticancer vaccine which includes polynucleotides or polypeptides, methods of treatment of cancer wherein such an anticancer vaccine is used as well as methods for producing the vaccine. The vaccine includes a polynucleotide with a nucleotide sequence encoding a targeting unit, a dimerization unit, a first linker and an antigenic unit. The antigenic unit includes from 3 to 50 antigenic subunits separated by a second linker with each antigenic subunit having at least a part of a cancer neoepitope sequence. The vaccine can include a polypeptide encoded by the polynucleotide or a dimeric protein with two polypeptides encoded by the polynucleotide.