The present disclosure provides a Farmington virus formulated to induce an immune response in a mammal against a tumour associated antigen. The Farmington virus may express an antigenic protein that includes an epitope from the tumour associated antigen. The Farmington virus may be formulated in a composition where the virus is separate from an antigenic protein that includes an epitope from the tumour associated antigen. The present disclosure also provides a prime:boost therapy for use in inducing an immune response in a mammal. The boost includes a Farmington virus, or a composition that includes a Farmington virus.

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 invention relates to immunogenic immune complexes, related compositions, and related methods.

The present invention relates to, in part, compositions comprising improved flagellin derived constructs and methods of using for vaccination, including adjuvants comprising flagellin-based agents.

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 invention provides a novel technology useful for a cancer vaccine therapy, that is, a pharmaceutical composition wherein a Toll-like receptor agonist, LAG-3 protein, a variant thereof or a derivative thereof, at least one immunogenic agent, and an immune checkpoint inhibitor are administered in combination.

The present disclosure relates to compositions and therapeutic methods for activating an immune response in a patient in need thereof. In a preferred embodiment, the subject methods and compositions are able to antagonize the activity of VISTA, a naturally occurring “checkpoint” protein which contributes to immune tolerance, optionally in combination with an antagonist of a second checkpoint pathway such as PD-1. For example, such methods and compositions may be suitable for preventing and treating colon cancer or another cancer. An exemplary VISTA antagonist, specifically, an anti-VISTA antibody, is demonstrated herein to activate an immune response against cancer cells in vitro and in vivo, thereby conferring protective anti-tumor immunity which decreased tumor burden. Additionally, an additive benefit was observed when a VISTA antagonist was used in combination with a second checkpoint protein antagonist, specifically, an antibody against PD-1 ligand (PD-L1).

The invention relates to an immunogenic composition comprising an HCMV gB antigen, an HCMV gH/gL/UL128/UL130/UL131 pentameric complex antigen and a Th1-inducing adjuvant. If further relates to the immunogenic composition for use as an HCMV vaccine.

The present invention in general relates to combinations of mRNA molecules encoding CD40, caTLR4 and CD70 with mRNA molecules encoding tumor-associated antigens for use as therapeutic vaccine in the treatment of metastatic cancer patients primarily with stable malignant melanoma disease, but also extending into other cancer types and to patient whose disease has shown partial response on prior therapy. Said uses may further encompass the administration of checkpoint inhibitors. The present invention further provides administration schemes for such therapies focusing on administration of the therapeutic into lymph nodes, so called intra-nodal therapy.