The present disclosure provides methods and kits for generating recombinant bacteriophage genomes.

A method of recovering viable phage from, for example, a crude phage preparation such as a lysate resulting from amplification of phage in bacterial cell culture is disclosed. The method may be “universal”; that is, applicable to the purification of a broad range of phage species and strains. The phage product resulting from the method may have an acceptably low endotoxin titer (e.g. less than 500 EU/ml) and sufficiently high phage titer (e.g. >1×10.sup.9 PFU/ml) for use in therapeutic applications.

The present invention relates to a method for producing a bacteriophage in a cell-free host-independent expression system and a corresponding composition comprising a cell lysate of an organism which is different to the host of the bacteriophage, a at least one bacteriophage-host specific factor and a genome of a bacteriophage. The respective kits are also encompassed. The invention moreover refers to a bacteriophage obtained by the method of the invention and uses thereof.

The system described herein for bacterial identification can be used as a point-of-care or lab-based diagnostic system. In some implementations, the system can be used to detect other foreign agents within blood or other samples. The system can include disposable microfluidic cartridges that are removable from the system. The microfluidic cartridges can receive a sample, such as a blood sample, that is suspected of containing bacterial cells and separate the bacterial cells from the blood sample. Once the bacterial cells are separated from the blood, the system can introduce the recombinant detector bacteriophages into the system that can infect the bacterial cells. The system can then detect the expression of reporter genes from the recombinant detector bacteriophages.

The present disclosure provides methods and kits for generating recombinant bacteriophage genomes.

The present invention provides methods for development of a virulent bacteriophage-based treatment for the control of plant diseases caused by Xylella fastidiosa. The invention further provides methods of isolating and propagating bacteriophage virulent to X. fastidiosa in a Xanthomonas bacterial host and for treating or reducing symptoms of X. fastidiosa infection in a plant. The invention further provides methods of isolating and propagating bacteriophage virulent to Xanthomonas axonopodis pv. citri and for treating or reducing symptoms of Xanthomonas axonopodis pv. citri infection in a plant.

A method of recovering viable phage from, for example, a crude phage preparation such as a lysate resulting from amplification of phage in bacterial cell culture is disclosed. The method may be universal; that is, applicable to the purification of a broad range of phage species and strains. The phage product resulting from the method may have an acceptably low endotoxin titer (e.g. less than 500 EU/ml) and sufficiently high phage titer (e.g. >1?10.sup.9 PFU/ml) for use in therapeutic applications.

The present invention provides methods for development of a virulent bacteriophage-based treatment for the control of plant diseases caused by Xylella fastidiosa. The invention further provides methods of isolating and propagating bacteriophage virulent to X. fastidiosa in a Xanthomonas bacterial host and for treating or reducing symptoms of X. fastidiosa infection in a plant. The invention further provides methods of isolating and propagating bacteriophage virulent to Xanthomonas axonopodis pv. citri and for treating or reducing symptoms of Xanthomonas axonopodis pv. citri infection in a plant.

A method of recovering viable phage from, for example, a crude phage preparation such as a lysate resulting from amplification of phage in bacterial cell culture is disclosed. The method may be universal; that is, applicable to the purification of a broad range of phage species and strains. The phage product resulting from the method may have an acceptably low endotoxin titer (e.g. less than 500 EU/ml) and sufficiently high phage titer (e.g. >1?10.sup.9 PFU/ml) for use in therapeutic applications.

The system described herein for bacterial identification can be used as a point-of-care or lab-based diagnostic system. In some implementations, the system can be used to detect other foreign agents within blood or other samples. The system can include disposable microfluidic cartridges that are removable from the system. The microfluidic cartridges can receive a sample, such as a blood sample, that is suspected of containing bacterial cells and separate the bacterial cells from the blood sample. Once the bacterial cells are separated from the blood, the system can introduce the recombinant detector bacteriophages into the system that can infect the bacterial cells. The system can then detect the expression of reporter genes from the recombinant detector bacteriophages.