The present invention relates to Podoviridae bacteriophage Pse-AEP-4 (accession number: KCTC 13166BP) isolated from nature, the Podoviridae bacteriophage Pse-AEP-4 having the capability to specifically kill Pseudomonas aeruginosa and having a genome represented by SEQ ID NO: 1, and a method for preventing or treating diseases induced by Pseudomonas aeruginosa by using a composition containing the Podoviridae bacteriophage Pse-AEP-4 as an active ingredient.

There is disclosed a method of engineering bacteriophages comprising: identifying a bacteriophage with only one attachment gene; isolating said bacteriophage; removing said attachment gene from the genome of said bacteriophage; and inserting a non-natural attachment gene into the genome of said bacteriophage wherein said non-natural attachment gene is specific for attaching to a selected bacteria. There is also disclosed a mutant bacteriophage comprising a heterologous nucleic acid sequence encoding a first specific attachment gene, the first specific attachment gene being different than an inactivated attachment gene and being specific for a selected bacteria. In another embodiment, there is disclosed a method of eliminating a microbial contaminant, the method comprising: obtaining one or more lytic enzymes produced by a mutant bacteriophage; applying the one or more lytic enzymes to a bacterial contaminant, without prior infection of the bacterial contaminant with a bacteriophage, to eliminate the bacterial contaminant.

There is disclosed a method of engineering bacteriophages comprising: identifying a bacteriophage with only one attachment gene; isolating said bacteriophage; removing said attachment gene from the genome of said bacteriophage; and inserting a non-natural attachment gene into the genome of said bacteriophage wherein said non-natural attachment gene is specific for attaching to a selected bacteria. There is also disclosed a mutant bacteriophage comprising a heterologous nucleic acid sequence encoding a first specific attachment gene, the first specific attachment gene being different than an inactivated attachment gene and being specific for a selected bacteria. In another embodiment, there is disclosed a method of eliminating a microbial contaminant, the method comprising: obtaining one or more lytic enzymes produced by a mutant bacteriophage; applying the one or more lytic enzymes to a bacterial contaminant, without prior infection of the bacterial contaminant with a bacteriophage, to eliminate the bacterial contaminant.

Insecticidal toxins described herein are fused toxin peptides made up of a targeting domain fused to a toxin domain. The targeting peptide generates a specific association with mosquitoes by causing the fused toxin peptide to bind mosquitoes in a way that leads to the insecticidal activity. Transgenic plants described herein are mosquitocidal by expressing an insecticidal toxin protein in nectar that includes a targeting peptide to ensure specificity against mosquitoes. These transgenic plants serve as role models for safety, since they are non-crop plants and specific to one mosquito species.

Insecticidal toxins described herein are fused toxin peptides made up of a targeting domain fused to a toxin domain. The targeting peptide generates a specific association with mosquitoes by causing the fused toxin peptide to bind mosquitoes in a way that leads to the insecticidal activity. Transgenic plants described herein are mosquitocidal by expressing an insecticidal toxin protein in nectar that includes a targeting peptide to ensure specificity against mosquitoes. These transgenic plants serve as role models for safety, since they are non-crop plants and specific to one mosquito species.

Disclosed are the H. zea nudivirus sequence and two additional related sequences from H. virescens and H. armigera nudiviruses for development of genetically modified nudiviruses capable of being sexually transmitted by an insect useful for controlling pest populations. Such genetically modified nudiviruses are capable of causing sterility in a target population of insects. Previously disclosed were insects infected with the previously disclosed genetically modified H. zea nudivirus, methods of making genetically modified nudiviruses, and methods of using genetically modified nudiviruses to control an insect pest population.

Disclosed are the H. zea nudivirus sequence and two additional related sequences from H. virescens and H. armigera nudiviruses for development of genetically modified nudiviruses capable of being sexually transmitted by an insect useful for controlling pest populations. Such genetically modified nudiviruses are capable of causing sterility in a target population of insects. Previously disclosed were insects infected with the previously disclosed genetically modified H. zea nudivirus, methods of making genetically modified nudiviruses, and methods of using genetically modified nudiviruses to control an insect pest population.

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.

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.

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.