The present invention provides a virus hybrid separation film and a method for manufacturing the same, capable of improving selective permeability using nano-pores of a virus. The separation film according to the present invention comprises: a porous support layer; and an active layer, disposed on the porous support layer, for having a target material selectively permeate thereinto, wherein the active layer comprises: a plurality of virus assemblies having pores; and an impermeable supporter. The impermeable supporter is positioned between the plurality of virus assemblies and supports the virus assemblies.

A rod-shaped plant virus having an interior surface and an exterior surface, and at least one imaging agent that is linked to the interior and/or exterior surface is described. The rod-shaped viruses can be combined into larger spherical nanoparticles. A rod-shaped plant virus or spherical nanoparticles including an imaging agent can be used in a method of generating an image of a tissue region of a subject such as a tumor or atherosclerotic tissue by administering the virus particle to the subject and generating an image of the tissue region of the subject to which the virus particle has been distributed.

The present invention provides a new species of tobamovirus and its use to identify plants comprising resistance against the virus.

The present invention relates to nanoparticles and their use to form nanocomposite material, in particular bionanocomposite material, specifically wherein the nanoparticles are formed using plant virus attached to a scaffold of cellulosic material and/or cellulose derived materials, in particular wherein said cellulosic material further comprises plant cell components, for example hemicellulose, pectin, protein or combinations thereof.

The present invention provides plant virus vectors developed from the Foxtail mosaic virus (FoMV). The vectors include a nucleic acid sequence encoding an infectious Foxtail mosaic virus (FoMV) with a functional movement encoding sequence operably linked to one or more regulatory elements functional in a plant. The plant virus vectors may be used to infect monocot plants, such as maize and can be used for VIGS, gene editing, gene expression or other transgenic protocols.

There is described a process for production of metal-coated virus particles or metallic nanoparticles, said process comprising admixing virus particles with plant material with reducing power and a metal salt, wherein the process can be provided in planta or ex planta and the virus particles aid the production of the metal-coated virus particles or metallic nanoparticles.

Methods are generally disclosed for attaching a cell binding motif to a carboxy end of a coat protein of a Tobacco Mosaic Virus particle to form a modified-TMV particle; and attaching a cell to the cell binding motif of the modified-TMV particle. Methods are also disclosed for incorporated virus particles, e.g., TMV virus particles into hydrogels.

At least one novel virus capable of infecting crazy ants (Nylanderia fulva) is isolated, along with polynucleotide sequences and amino acid sequences of the virus. The virus is capable of be used as a biopesticide to control populations of crazy ants.

Applicants describe herein TMGMV-derived spherical nanoparticles (SNPs) that used entrap small molecule cargo for improved loading efficiency while minimizing upstream processing steps.