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.

The present disclosure provides a chimeric receptor binding protein (RBP) resistant to proteolytic digestion wherein said RBP comprises a portion of a receptor binding protein derived from a bacteriophage fused through a designed linker region consisting of 1 to 70 amino acids, to a portion of a receptor binding protein derived from a different bacteriophage, wherein said linker region is designed to be resistant to proteolytic digestion.

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.

The present description relates to chimeric bacteriophage lysins useful for the identification and/or reduction of staphylococcal populations. For example, a chimeric bacteriophage lysin was engineered and shown to effectively kill all strains of staphylococci tested including antibiotic resistant methicillin-resistant S. Aureus and VISA.

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.

The invention relates to C. acnes strains carrying DNA vectors for the production of recombinant C. acnes phages. The invention encompasses a C. acnes producer cell carrying DNA vectors, with a template for recombination with C. acnes phage genome leading to the insertion of a gene of interest, for the production of recombinant phages that can lead to the transgene expression into C. acnes infected by the recombinant phage. The invention encompasses, C. acnes strains containing these vectors, C. acnes recombinant phages and methods of using these recombinant phages.

The present invention refers to lambda integrases comprising at least one amino acid mutation at positions 43, 319 and 336 of the lambda integrase as set forth in SEQ ID NO: 1. The invention further refers to nucleic acid molecules comprising the nucleotide sequence encoding the mutant lambda integrase and to host cells containing these nucleic acid molecules. The invention also refers to methods of recombining a nucleic acid of interest into a target nucleic acid in the presence of the mutant lambda integrase and sequence specific recombination kits.

The present disclosure provides compositions and methods for introducing or enhancing Aca activity in prokaryotic cells. The provided compositions and methods can be used to inhibit Acr activity in prokaryotic cells, thereby enhancing endogenous or exogenous CRISPR-Cas activity. Cells, polynucleotides, plasmids, phage, and other elements for practicing the present methods are also provided.

The invention relates to C. acnes carrying DNA vectors with a C. acnes phage packaging signal and a gene of interest. The invention encompasses a C. acnes producer cell carrying DNA vectors, with a C. acnes phage packaging signal and a gene of interest, for the production of phage-derived particles that can robustly transduce C. acnes receiver cell allowing transgene expression. The invention encompasses C. acnes phage-derived particles carrying these vectors, C. acnes containing these vectors or modified by transduction of these phage-derived particles, and methods of using these phage-derived particles.

The present disclosure relates generally to bacterial delivery vehicles for use in efficient transfer of a desired payload into a target bacterial cell. More specifically, the present disclosure relates to bacterial delivery vehicles with desired host ranges based on the presence of a chimeric receptor binding protein (RBP) composed of a fusion between the N-terminal region of a RBP derived from a lambda-like bacteriophage and the C-terminal region of a different RBP.