In alternative embodiments, provided are compositions, including products of manufacture and kits, and methods, for purifying bacteriophage. Provided herein is are practicable methods, or protocols, that are “Good Laboratory Manufacturing Practice” (GLMP), for phage isolation, selection, liter-scaled cultivation, and purification. In alternative embodiments, GLMP protocols as provided herein employ membrane filtration processes to yield at least about 300 treatment doses at about 10.sup.9 plaque-forming units with endotoxin levels within human therapeutic regulatory limits. In alternative embodiments, provided are formulations or pharmaceutical preparations of bacteriophage comprising 10.sup.9 PFU, 10.sup.10 PFU, 10.sup.11 PFU, or 10.sup.12 PFU or more per unit dose and endotoxin levels below about 5.5 EU.Math.mL.sup.−1, or below about 5.0 EU.Math.mL.sup.−1.

The subject matter of the instant invention relates to methods of compounding compositions comprising bacteriophage effective for treating bacterial infections, including but not limited to, multidrug resistant bacterial infections. The invention also relates to compositions, bacterial diversity sets, and phage libraries prepared according to the methods of the instant invention.

The present invention relates to a method for preparing a bactericidal phage vector, (pharmaceutical) compositions comprising such phage vectors, also for use in treating diseases, particularly those caused by (antimicrobial resistance) bacterial cells.

The present disclosure features compositions and methods for the treatment of bacterial infections, such as bacterial infections caused by bacterial cells residing within a host cell (e.g., a mammalian cell, e.g., immune cell, e.g., macrophage or dendritic cell). The compositions and methods include delivering antimicrobial agents to specifically target the intracellular compartment (endosome, phagosome, lysosome, or cytosol) in which the bacterial cell resides.

There is proposed a method for the sterilization of products containing bacteriophages in a manner that will allow the bacteriophages to retain their activity and infectivity. Products containing bacteriophages are exposed to supercritical CO.sub.2 under conditions causing little or no damage to structural integrity of the bacteriophages or to the structural properties of biodegradable scaffolds containing the bacteriophages.

A composition or matrix comprising a bacteriophage and nanofibrillar cellulose or a derivative thereof in a wet or dry state is disclosed.

The present disclosure features compositions and methods for the treatment of bacterial infections, such as bacterial infections caused by bacterial cells residing within a host cell (e.g., a mammalian cell, e.g., immune cell, e.g., macrophage or dendritic cell). The compositions and methods include delivering a bacteriophage and an antibacterial lytic protein to the intracellular computment (endosome, phagosome, lysosome, or cytosol) in which the bacterial cell resides.

The subject matter of the instant invention relates to methods of compounding compositions comprising bacteriophage effective for treating bacterial infections, including but not limited to, multidrug resistant bacterial infections. The invention also relates to compositions, bacterial diversity sets, and phage libraries prepared according to the methods of the instant invention.

Described herein is a protein display selection method which uncouples a protein of interest (POI) library from the display selection system. Display of the POI can be achieved by forming a covalent bond between the POI and the anchor protein post expression either by enzymatic protein ligation (e.g. SpyLigase, SnoopLigase, sortase, butelase, peptiligase etc.) or by spontaneous covalent bond formation (e.g. SpyTag/SpyCatcher, SnoopTag/SnoopCatcher, etc.).

The POI library is fused to a tethering sequence, for example SpyTag, at the C-terminus of the POI which then forms a covalent bond to a capture sequence found on an anchor protein, for example, the SpyCatcher-fused anchor protein, e.g., a SpyCatcher-geneIII protein (SpyCatcher-pIII) fusion, for the most common form of phage display. Nucleic acid constructs, host cell systems and methods of producing the protein display systems are also provided.

Disclosed herein are methods for the production of mutant bacteriophages with altered host range. Additionally, disclosed herein are methods and systems for rapid detection of microorganisms such as Listeria spp. in a sample. A genetically modified bacteriophage is also disclosed which comprises an indicator gene in the late gene region. The specificity of the bacteriophage, such as Listeria-specific bacteriophage, allows detection of a specific microorganism, such as Listeria spp. and an indicator signal may be amplified to optimize assay sensitivity.