There is described a kit for use in inducing an immune response in a mammal, the kit includes: a first virus that expresses MAGEA3, Human Papilloma Virus E6/E7 fusion protein, human Six-Transmembrane Epithelial Antigen of the Prostate protein, or Cancer Testis Antigen 1, or a variant thereof as an antigenic protein and that is formulated to generate an immunity to the protein or variant thereof in the mammal. The kit also includes a Maraba MG1 virus encoding the same antigen, or a variant of the same antigen. The Maraba MG1 virus is formulated to induce the immune response in the mammal. The first virus is immunologically distinct from the Maraba MG1 virus.

There is described a kit for use in inducing an immune response in a mammal, the kit includes: a first virus that expresses MAGEA3, Human Papilloma Virus E6/E7 fusion protein, human Six-Transmembrane Epithelial Antigen of the Prostate protein, or Cancer Testis Antigen 1, or a variant thereof as an antigenic protein and that is formulated to generate an immunity to the protein or variant thereof in the mammal. The kit also includes a Maraba MG1 virus encoding the same antigen, or a variant of the same antigen. The Maraba MG1 virus is formulated to induce the immune response in the mammal. The first virus is immunologically distinct from the Maraba MG1 virus.

The present invention provides methods and compositions for protein delivery. The invention features virus like particles, methods of making virus like particles and methods of using virus like particles to deliver proteins to a cell, to provide protein therapy and to treat diseases or disorders. The invention also features methods of targeting a protein to a cell, methods of protein therapy and methods of treating diseases or disorders using a TUS protein, a NLS or NES identified from full length TUS.

There is described a kit for use in inducing an immune response in a mammal, the kit includes: a first virus that expresses MAGEA3, Human Papilloma Virus E6/E7 fusion protein, human Six-Transmembrane Epithelial Antigen of the Prostate protein, or Cancer Testis Antigen 1, or a variant thereof as an antigenic protein and that is formulated to generate an immunity to the protein or variant thereof in the mammal. The kit also includes a Maraba MG1 virus encoding the same antigen, or a variant of the same antigen. The Maraba MG1 virus is formulated to induce the immune response in the mammal. The first virus is immunologically distinct from the Maraba MG1 virus.

Compositions and methods useful for treating and/or preventing a Zika virus infection are provided.

There is described a kit for use in inducing an immune response in a mammal, the kit includes: a first virus that expresses MAGEA3, Human Papilloma Virus E6/E7 fusion protein, human Six-Transmembrane Epithelial Antigen of the Prostate protein, or Cancer Testis Antigen 1, or a variant thereof as an antigenic protein and that is formulated to generate an immunity to the protein or variant thereof in the mammal. The kit also includes a Maraba MG1 virus encoding the same antigen, or a variant of the same antigen. The Maraba MG1 virus is formulated to induce the immune response in the mammal. The first virus is immunologically distinct from the Maraba MG1 virus.

There is described a kit for use in inducing an immune response in a mammal, the kit includes: a first virus that expresses MAGEA3, Human Papilloma Virus E6/E7 fusion protein, human Six-Transmembrane Epithelial Antigen of the Prostate protein, or Cancer Testis Antigen 1, or a variant thereof as an antigenic protein and that is formulated to generate an immunity to the protein or variant thereof in the mammal. The kit also includes a Maraba MG1 virus encoding the same antigen, or a variant of the same antigen. The Maraba MG1 virus is formulated to induce the immune response in the mammal. The first virus is immunologically distinct from the Maraba MG1 virus.

Provided herein are glycoprotein particles comprising one or more glycoproteins, or fragments thereof that enhance targeting of a particle to a cell or tissue. A glycoprotein particle as provided herein may be used for any application, including therapeutic and diagnostic treatments.

Described herein are minimal virus-like particles (mVLPs), comprising a membrane comprising a phospholipid bilayer with one or more ectodomain-truncated VSV envelope glycoproteins on the external side; and a biomolecule cargo disposed in the core of the mVLP on the inside of the membrane. Preferably, the mVLPs do not comprise a protein from viral gag, pro, pol, or other viral proteins that reside inside of enveloped particles. Also described are methods of use of the mVLPs for delivery of the biomolecule cargo to cells.

Described herein are programmable tropism virus-like particles (ptVLPs), comprising a membrane comprising a phospholipid bilayer with one or more wild-type or mutant/truncated virus-derived glycoproteins on the external side. The virus-derived envelope glycoprotein(s) can optionally be fused directly to a targeting domain (e.g., peptide, single chain variable fragment (scFv), nanobody, fibronectin type 3 domain (FN3), arginylglycylaspartic acid motif (RGD), single variable domain on a heavy chain/nanobody (VHH), variable domain of new antigen receptor (VNAR), darpin, or other targeting ligand), and/or can be present in combination with a membrane-anchored targeting domain. A biomolecule cargo (preferably fused to a membrane recruitment domain, such as a Pleckstrin homology domain) can be disposed in the core of the ptVLP. Preferably, the ptVLP does not comprise a protein from any human endogenous or exogenous viral gag, pro, pol, or other viral proteins that reside inside of enveloped particles.