The present inventors have found that innate immune response and T cell exhaustion pathway are more greatly over-expressed in pigs than cattle, such that the pigs are less likely to form adaptive and humoral immune responses than cattle. It would be suggested herein an innovative strategy for improvement of abnormal immune responses in pigs by simultaneously inducing potent cellular and humoral immune responses and applying T cell agonists as a new vaccine adjuvant. This result may provide an important clue for understanding a difference in the immune response between the cattle and pigs, while suggesting a method for maximizing the immune response and vaccine efficacy, which are less expressed in pigs than cattle.

The present invention relates to single dose parenteral vaccine compositions comprising mixtures of monovalent Norovirus virus-like particles. Methods of conferring protective immunity against Norovirus infections in a human subject by administering such compositions are also disclosed.

The instant invention provides various formulations comprising combinations of immunostimulating oligonucleotides, polycationic carriers, sterols, saponins, quaternary amines, TLR-3 agonists, glycolipids, and MPL-A or analogs thereof in oil emulsions, use thereof in preparations of immunogenic compositions and vaccines, and use thereof in the treatment of animals.

An immunogenic composition, a periodontal vaccine formulation containing the immunogenic composition, and methods for treating or preventing periodontal disease are provided, where the methods involves administering an immunologically effective amount of the composition or vaccine formulation to a subject. The immunogenic composition contains at least one polypeptide that comprises: an Mfa1 antigen sequence that is substantially homologous to an immunogenic amino acid sequence from an Mfa1 fimbrilin protein of a Porphyromonas bacterium; and an HA1 antigen sequence, an HA2 antigen sequence, or both an HA1 antigen sequence and an HA2 antigen sequence, wherein the HA1 antigen sequence is substantially homologous to an immunogenic amino acid sequence from an RgpA Gingipain hemagglutinin domain 1 contained within an RgpA Gingipain protein of a Porphyromonas bacterium, and the HA2 antigen sequence is substantially homologous to an immunogenic amino acid sequence from an RgpA Gingipain hemagglutinin domain 2 contained within an RgpA Gingipain protein of a Porphyromonas bacterium.

Non-liposome, non-micelle particles formed of a lipid, an additional adjuvant such as a TLR4 agonist, a sterol, and a saponin are provided. The particles are porous, cage-like nanoparticles, also referred to as nanocages, and are typically between about 30 nm and about 60 nm. In some embodiments, the nanocages include or are administered in combination with an antigen. The particles can increase immune responses and are particularly useful as adjuvants in vaccine applications and related methods of treatment. Preferred lipids, additional adjuvants including TLR4 agonists, sterols, and saponins, methods of making the nanocages, and method of using them are also provided.

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 application relates to compositions capable of inducing an immune response against Varicella zoster virus, methods of administering such compositions, and methods of producing such compositions.

A method of treating a synucleinopathy with a peptide (C)DQPVLPD (SEQ ID NO: 59), (C)DMPVLPD (SEQ ID NO: 60), (C)DSPVLPD (SEQ ID NO: 61), (C)DQPVLPDN (SEQ ID NO: 64), (C)DMPVLPDN (SEQ ID NO: 65), (C)DSPVLPDN (SEQ ID NO: 66), (C)HDRPVTPD (SEQ ID NO: 70), (C)DRPVTPD (SEQ ID NO: 71), (C)DVPVLPD (SEQ ID NO: 72), (C)DTPVYPD (SEQ ID NO: 73), (C)DTPVIPD (SEQ ID NO: 74), (C)HDRPVTPDN (SEQ ID NO: 75), (C)DRPVTPDN (SEQ ID NO: 76), (C)DVPVLPDN (SEQ ID NO: 78), (C)DTPVYPDN (SEQ ID NO: 79), (C)DQPVLPDG (SEQ ID NO: 81), (C)DMPVLPDG (SEQ ID NO: 82), (C)DSPVLPDG (SEQ ID NO: 83), (C)DHPVHPDS (SEQ ID NO: 86), (C)DMPVSPDR (SEQ ID NO: 87), (C)DRPVYPDI (SEQ ID NO: 90), (C)DHPVTPDR (SEQ ID NO: 91), (C)DTPVLPDS (SEQ ID NO: 93), (C)DMPVTPDT (SEQ ID NO: 94), (C)DAPVTPDT (SEQ ID NO: 95), (C)DSPVVPDN (SEQ ID NO: 96), (C)DLPVTPDR (SEQ ID NO: 97), (C)DSPVHPDT (SEQ ID NO: 98), (C)DAPVRPDS (SEQ ID NO: 99), (C)DMPVWPDG (SEQ ID NO: 100), (C)DRPVQPDR (SEQ ID NO: 102), (C)YDRPVQPDR (SEQ ID NO: 103), (C)DMPVDADN (SEQ ID NO: 105), DQPVLPD(C) (SEQ ID NO: 106), and DMPVLPD(C) (SEQ ID NO: 107.

Embodiments of the disclosure include methods and compositions useful for treating cancer in an immunogenic manner so as to elicit local tumor regression, while priming systemic immunity. In one embodiment, there is expansion of tumor-specific immune cells through administration of fibroblasts, either natural or modified in an intratumoral and/or peritumoral manner. In other embodiments, manipulation of a local tumor microenvironment is achieved by injections of immune-modulating fibroblasts to facilitate expansion of immune effector cells, which are subsequently re-stimulated in the periphery by antigenic exposure. In another embodiment, agents are provided that allow for systemic derepression of immunity, while optionally augmenting ability of immune effector cells to expand and kill tumor cells.

The present application relates to method of vaccinating a subject against infection by an enveloped virus. The method includes providing a compound of the Formula (I) as described herein, and contacting the compound of Formula (I) with an isolated enveloped virus, having a membrane, to inactivate the membrane of the isolated enveloped virus. The subject is then treated with the enveloped virus having an inactivated membrane to vaccinate the subject against the enveloped virus. Further disclosed is an ex vivo vaccine composition including the compound of Formula (I) and an enveloped virus.