The current invention pertains to a molecular conjugate comprising an antagonist of a cell surface receptor specific to a target cell and an immune effector, such as a T cell modulator, conjugated to the antagonist. The target cell can be a cell responsible for development of a disease in a subject, for example, a cancer cell. In certain embodiments, the immune effector is an immune effector protein or an immune effector fragment thereof. The current invention also pertains to a method of treating a disease in a subject, the method comprising administering to the subject a pharmaceutically effective amount of the molecular conjugates of the current invention to the subject. The methods of the current invention can be used to treat cancer, such as breast cancer, ovarian cancer, prostate cancer, lung cancer, pancreatic cancer, or melanoma.

Disclosed herein are methods and exemplary compositions associated with virus purification, antigen purification, and conjugation of virus and proteins (e.g., antigen) to form vaccines for delivery of immunological and other therapeutic agents, exemplary aspects of which may include harvesting viral and antigenic substances from source organisms; a purification platform comprising chemical separation and size-difference separation for the removal of contaminants, debris and impurities from the viral and protein (e.g. antigenic, including influenza hemagglutinin antigens) substances, as well as their concentration and collection; and a conjugation platform providing activation of the virus at a pH that increases binding rate and binding propensity between the virus and the protein, wherein embodiments related to the conjugation platform include controlling the ratio of virus to protein.

Disclosed herein are methods and exemplary compositions associated with virus purification, antigen purification, and conjugation of virus and proteins (e.g., antigen) to form vaccines for delivery of immunological and other therapeutic agents, exemplary aspects of which may include harvesting viral and antigenic substances from source organisms; a purification platform comprising chemical separation and size-difference separation for the removal of contaminants, debris and impurities from the viral and protein (e.g. antigenic, including influenza hemagglutinin antigens) substances, as well as their concentration and collection; and a conjugation platform providing activation of the virus at a pH that increases binding rate and binding propensity between the virus and the protein, wherein embodiments related to the conjugation platform include controlling the ratio of virus to protein.

Described herein are compositions including an immune effector cells that are chemically modified at the surface with one or more active agent-loaded nano- or micro-particles for controlled release of the active agent. Exemplary drug-loaded nanoparticles include crosslinked multilayer liposome (CMLV) encapsulating an A2a receptor inhibitor. The modified immune effector cells may also present one or more chimeric antigen receptors (CARs) on the surface. Also provided are methods of using the same to treat cancer.

The present invention relates to a novel antibody against HERV-K envelope that targets a conserved region not affected by glycosylation or by native conformation, and its use in diagnostics and/or in therapy.

In various embodiments nanoparticle drug delivery vehicles are provided that specifically deliver a cargo to a target pathogenic organism. In certain embodiments the drug delivery vehicle comprises a mesoporous silica nanoparticle comprising a plurality of pores and an outer surface through which the pores are disposed; a cargo disposed in the pores; one or more antigens attached to the surface of the nanoparticle; an antibody that specifically binds the antigens and are bound to the antigens, wherein the antibody inhibits diffusion of the cargo out of the pores and permit release of the cargo when the drug delivery vehicle is in the presence of the antigen or a pathogen displaying the antigen.

The current invention pertains to a molecular conjugate comprising an antagonist of a cell surface receptor specific to a target cell and an immune effector, such as a T cell modulator, conjugated to the antagonist. The target cell can be a cell responsible for development of a disease in a subject, for example, a cancer cell. In certain embodiments, the immune effector is an immune effector protein or an immune effector fragment thereof. The current invention also pertains to a method of treating a disease in a subject, the method comprising administering to the subject a pharmaceutically effective amount of the molecular conjugates of the current invention to the subject. The methods of the current invention can be used to treat cancer, such as breast cancer, ovarian cancer, prostate cancer, lung cancer, pancreatic cancer, or melanoma.

The present invention provides methods, compositions, systems, and kits comprising nano-satellite complexes and/or serum albumin carrier complexes, which are used for modulating antigen-specific immune response (e.g., enhancing anti-tumor immunity). In certain embodiments, the nano-satellite complexes comprise: a) a core nanoparticle complex comprising a biocompatible coating surrounding a nanoparticle core; b) at least one satellite particle attached to, or absorbed to, the biocompatible coating; and c) an antigenic component conjugated to, or absorbed to, the at least one satellite particle component. In certain embodiments, the complexes further comprise: d) a type I interferon agonist agent. In some embodiments, the serum albumin complexes comprise: a) at least part of a serum albumin protein, b) an antigenic component conjugated to the carrier protein, and c) a type I interferon agonist agent.

The present description relates to glycoconjugates, glycoconjugate immunogens and glycoconjugate vaccines comprising carbohydrate antigens coupled to immunogenic carrier proteins, or materials used for detection and screening of resulting antibodies. Improved methods of more directly and precisely conjugating carbohydrate antigens to free thiol groups of immunogenic carrier proteins are described, including click-chemistry approaches based on photocatalytic thiol-ene reactions.

1H-Imidazo[4,5-c]quinolin-4-amines substituted at the 1-position with a substituent bearing a hydrazinobenzamide or hydrazinonicotinamide, a salt thereof, or a protected hydrazinobenzamide or hydrazinonicotinamide and conjugates made from such compounds are disclosed. Pharmaceutical compositions containing the compound or the conjugate, methods of making a conjugate, and methods of use of the compounds or conjugates as immunomodulators for inducing cytokine biosynthesis in an animal and for vaccinating an animal are also disclosed.