The present invention relates to vectors, such as DNA plasmids, comprising multiple nucleic acid sequences engineered to be co-expressed as separate molecules. Such separate molecules include a first polypeptide, wherein the first polypeptide comprises a targeting unit that targets antigen-presenting cells, a multimerization unit, such as dimerization unit, and an antigenic unit comprising one or more T cell epitopes of a self-antigen, an allergen, an alloantigen or a xenoantigen, and one or more immunoinhibitory compounds

A method of targeting bacterially-derived, intact minicells to specific, non-phagocytic mammalian cells employs bispecific ligands to deliver nucleic acids efficiently to the mammalian cells. Bispecific ligands, comprising (i) a first arm that carries specificity for a bacterially-derived minicell surface structure and (ii) a second arm that carries specificity for a non-phagocytic mammalian cell surface receptor are useful for targeting minicells to specific, non-phagocytic mammalian cells and causing endocytosis of minicells by non-phagocytic cells.

Methods and compositions are provided for delivering a polynucleotide encoding a gene of interest to a target cell using a virus. The virus envelope comprises a cell-specific binding determinant that recognizes and binds to a component on the target cell surface, leading to endocytosis of the virus. A separate fusogenic molecule is also present on the envelope and facilitates delivery of the polynucleotide across the membrane and into the cytosol of the target cell. The methods and related compositions can be used for treating patients having suffering from a wide range of conditions, including infection, such as HIV; cancers, such as non-Hodgkin's lymphoma and breast cancer; and hematological disorders, such as severe combined immunodeficiency.

A method of targeting bacterially-derived, intact minicells to specific, non-phagocytic mammalian cells employs bispecific ligands to deliver nucleic acids efficiently to the mammalian cells. Bispecific ligands, comprising (i) a first arm that carries specificity for a bacterially-derived minicell surface structure and (ii) a second arm that carries specificity for a non-phagocytic mammalian cell surface receptor are useful for targeting minicells to specific, non-phagocytic mammalian cells and causing endocytosis of minicells by non-phagocytic cells.

The present invention concerns a polymeric material for the production of a non-viral nanoparticle. The polymeric material comprises (i) a hydrophilic linear polymer having a first end and a second end, (iii) a cross-linkable cationic polymer covalently bonded to the first end of the hydrophilic linear polymer, and (iii) at least one targeting/penetrating peptide covalently associated to the second end of the hydrophilic linear polymer. Also disclosed herein are nanoparticles produced with these polymeric material, processes for making the polymeric material and the nanoparticles as well as use of the nanoparticles.

In one embodiment, the invention provides an HSV vector comprising a mutant gB and/or a mutant gH glycoprotein, where the viral envelope further comprises a non-native ligand specific for a protein present on the surface of a predetermined cell type. In another embodiment, the invention provides an HSV vector comprising (a) a mutant gC and/or gD envelope glycoprotein which comprises a non-native ligand specific for a protein present on the surface of a predetermined cell type; and (b) a mutant envelope glycoprotein other than gD.

The present invention provides an HSV vector comprising an envelope comprising one or more mutant gB and/or gH envelope glycoproteins, whereby the HSV vector exhibits at least 25% increased rate-of-entry after 20 minutes when assayed at 30 C. or 37 C. in Vero cells after first incubating at 4 C. relative to a control HSV comprising wild-type gB and gH glycoproteins. The invention also provides a viral stock comprising the inventive HSV vector.

The invention provides modified HSV vectors that exhibit enhanced entry of cells, either through direct infection and/or lateral spread. In one aspect, HSV vectors of the present invention can directly infect cells through interaction with cell proteins other than typical mediators of HSV infection. In another aspect, the invention provides an HSV vector, which exhibits lateral spread in cells typically resistant to HSV lateral spread, such as cells lacking gD receptors. The invention further provides DNA encoding mutant forms of the HSV gB and gH glycoproteins, stocks of the inventive virus, and methods for effecting viral targeting and efficient entry of cells. The invention also pertains to the use of the inventive vectors for treating cancers.