The disclosure provides RNA vaccines for seasonal influenza virus as well as methods of using the vaccines.

Systems and methods to increase the efficacy of vaccines that require or are rendered more effective with T cell mediated immunity are described. The systems and methods utilize polynucleotides that genetically modify T cells to express a T cell receptor specific for an administered vaccine antigen.

The disclosure relates to stable RSV F proteins and immunogenic compositions containing the same, as well as methods of using the immunogenic compositions and compositions comprising the RSV F proteins.

Described herein are compositions and methods for the reducing a risk of contracting a respiratory disease in a subject or reducing a risk of transmitting a respiratory disease from a first subject to a second subject. In some cases, a composition or method described herein can comprise a modulator (e.g., a pattern recognition receptor, such as a STING agonist, for instance cGAMP) In some cases, a composition or method described herein can comprise a liposome, which may be used to encapsulate one or more STING agonists. In some cases, a liposome of a composition or method described herein may comprise one or more antigens attached to, integrated into, or associated with a liposomal membrane of the liposome.

Disclosed herein are self-replicating RNA molecules encoding prostate neoantigens, vaccines, and method of treating and preventing prostate cancer using the self-replicating RNA molecules and vaccines.

HIV-1 Env ectodomain trimers stabilized in a prefusion mature closed conformation and methods of their use and production are disclosed. In several embodiments, the HIV-1 Env ectodomain trimers and/or nucleic acid molecules can be used to generate an immune response to HIV-1 in a subject. In additional embodiments, the therapeutically effective amount of the HIV-1 Env ectodomain trimers can be administered to a subject in a method of treating or preventing HIV-1 infection.

The present invention is directed to an artificial nucleic acid and to polypeptides suitable for use in treatment or prophylaxis of an infection with Henipavirus, particularly Hendra virus and/or Nipah virus or a disorder related to such an infection. In particular, the present invention concerns a Hendra virus and/or Nipah virus vaccine. The present invention is directed to an artificial nucleic acid, polypeptides, compositions and vaccines comprising the artificial nucleic acid or the polypeptides. The invention further concerns a method of treating or preventing a disorder or a disease, first and second medical uses of the artificial nucleic acid, polypeptides, compositions and vaccines. Further, the invention is directed to a kit, particularly to a kit of parts, comprising the artificial nucleic acid, polypeptides, compositions and vaccines.

The present disclosure provides a nanoparticle comprising a positively-charged surface and an interior comprising (i) a core and (ii) at least two nucleic acid layers, wherein each nucleic acid layer is positioned between a cationic lipid bilayer, wherein the nanoparticle comprises RNA molecules encoding a SARS-CoV-2 protein. Methods of making such nanoparticles are further provided herein. Additionally, related cells, populations of cells, pharmaceutical compositions comprising the presently disclosed nanoparticles are provided. Methods of increasing an immune response against a tumor in a subject, methods of delivering RNA molecules to an intra-tumoral microenvironment, lymph node, and/or a reticuloendothelial organ in a subject, and methods of treating a subject with a disease are furthermore provided.

The present invention is related to biotechnology, particularly to the field of human health. It provides new vaccine compositions that comprise as active principle a system that contains the recombinant human EGF, or peptides thereof, and a carrier protein or peptide, bound to a nucleus constituted by inorganic nanoparticles, with nanometric or submicrometric scale dimensions. These vaccine compositions are useful for the chronic treatment of cancer and have as advantages that their administration does not result in the appearance of adverse effects at the injection site and that they do not accumulate in the body.

Compositions and methods for treating a viral infection may comprise use of an adenoviral vector. An adenoviral vector of the present disclosure may comprise a non-human adenoviral genome with one or more gene locus functionally removed and a transgene. A method of treating a viral infection may comprise administering a composition comprising an adenoviral vector of the present disclosure, to a subject and reducing the infectivity or transmission of the virus. Intranasal administration provides enhance protection of the upper respiratory tract of a subject relative to intramuscular administration.