A modified bacteriophage capable of infecting a plurality of different target bacteria, which bacteriophage includes a toxin gene encoding a toxin protein which is toxic to the target bacteria; wherein the bacteriophage is lytic; and wherein the bacteriophage expresses host range determinant proteins which have a plurality of bacterial host specificities.

Provided herein are methods and compositions for killing a target bacterium. Also disclosed are engineered bacteriophages.

In alternative embodiments, provided are compositions comprising chemically or structurally modified bacteriophages of the genus Caudovirales having an exterior or outer surface comprising at least one heterologous carbohydrate binding domain (CBD) comprising a lectin or a plurality of additional homologous CBDs, or more CBDs than found on a comparable wild type (WT) bacteriophage.

Disclosed here are recombinant bacteriophages with tail fibers encoded by at least two subsets of genomic fragments from different bacteriophage having different host ranges.

The present invention relates to bacteriophage therapy. More particularly, the present invention relates to novel bacteriophages having a high specificity against Pseudomonas aeruginosa strains, their manufacture, components thereof, compositions comprising the same and the uses thereof in phage therapy.

Compositions for a phage particle are disclosed. The phage particle is non-replicating and includes at least one heterologous nucleic acid sequence that is capable of being expressed in a target bacteria. The expressed heterologous nucleic acid sequence is non-lethal to the target bacteria.

The present invention concerns a production bacterial cell for producing phage particles or phage-derived delivery vehicles, said production bacterial cell stably comprising at least one phage structural gene(s) and at least one phage DNA packaging gene(s), said phage structural gene(s) and phage DNA packaging gene(s) being derived from a first type of bacteriophage,

wherein the expression of at least one of said phage structural gene(s) and/or at least one of said phage DNA packaging gene(s) in said production bacterial cell is controlled by at least one induction mechanism, and

wherein said production bacterial cell is from a bacterial species or strain different from the bacterial species or strain from which said first type of bacteriophage comes and/or that said first type of bacteriophage targets.

Provided herein are methods and compositions for killing a target bacterium. Also disclosed are engineered bacteriophages.

Disclosed herein are compositions, methods, kits and systems for rapid detection of microorganisms using a reproduction-deficient indicator bacteriophage. The specificity of such reproduction-deficient indicator bacteriophage for binding and infecting particular microorganisms of interest allows targeted and sensitive detection of a microorganism of interest.

Cancer eradicating engineered bacteriophage are described that can display a high copy number of a targeting polypeptide that can bind a surface antigen of a cancer cell. The bacteriophage can also display a high copy number of a cancer therapy, one or more of a drug, a toxin, an inhibitor, a radionuclide, etc. The targeting polypeptides and the cancer therapies can be directly or indirectly fused to coat proteins of the phage. The engineered phage can exhibit high avidity for cancer cells and can deliver a large dose of a cancer therapy per particle to the cell.