A prophylactic and/or therapeutic food composition for control of deformed wing vims (DWV) in bees and/or bee larvae, and methods of using and making the same. Bee feed compositions comprising anti-DWV antibodies dispersed in an edible base composition. Use of recombinant VP1, VP2, VP3, and/or VP4 capsid proteins, or VLPs of deformed wing vims (DWV) to passively generate anti-DWV antibodies in chicken egg yolks, and use of such anti-DWV antibodies for prophylaxis or treatment of deformed wing virus in the bees and/or larvae.

A method of treating cancer in a subject in need thereof includes administering in situ to the cancer a therapeutically effective amount of a virus or virus-like particle.

A method of treating cancer in a subject in need thereof includes administering in situ to the cancer a therapeutically effective amount of a virus or virus-like particle.

Methods and nucleic acid sequences for the synthesis of biotemplates in a non-plant based expression system are provided. Such biotemplates include Barley stripe mosaic virus viral-like particles (BSMV-VLPs) that are capable of self-assembly due to being operatively linked with an origin of self-assembly with the Barley stripe mosaic virus capsid protein (BSMV-CP). Also provided are BSMV-VLPs that are capable of self-assembly due one or more site-directed mutations on the BSMV-CP, and BSMV-VLPs that exhibit enhanced stability due to such site-directed mutation(s).

The present invention relates to macromolecular complexes comprising micron-scale networks which include binding motifs thereon which allow the covalent bonding of the micron-scale networks to particles which provide nanoscale display surfaces. In particular the present invention relates to micron-scale networks of TMV coat proteins comprising a peptide tag (e.g. SpyTag) and particles providing a nanoscale display surface comprising GFP and a corresponding binding protein (e.g. SpyCatcher) wherein the peptide tag and binding protein pair are capable of spontaneously forming a covalent bond.

An agent is described that includes a plant virus particle or VLP conjugate to TRAIL. Associating TRAIL with the plant virus particle or VLP serves to both target cancer cells and induce their apoptosis. The agent can therefore be used for a method of treating cancer in a subject.

A method of treating cancer in a subject in need thereof includes administering in situ to the cancer a therapeutically effective amount of a virus or virus-like particle.

Photodynamic virus particles including a plant virus particle associated with a photosensitizing agent are described. Methods of treating cancer in a subject by administering to the subject a therapeutically effective amount of the photodynamic virus particles and illuminating a cancer-bearing region of the subject to activate the photodynamic virus particles are also described.

A melt processed viral nanoparticle construct for delivery of virus or virus-like particles to a site of interest includes a degradable polymer matrix and a plurality of virus or virus-like particles encapsulated within the degradable polymer matrix. The nanoparticle construct upon administration to the site of interest providing a sustained release of the virus or virus-like particles and/or nanoparticles upon degradation of the polymer matrix.

A melt processed viral nanoparticle construct for delivery of virus or virus-like particles to a site of interest includes a degradable polymer matrix and a plurality of virus or virus-like particles encapsulated within the degradable polymer matrix. The nanoparticle construct upon administration to the site of interest providing a sustained release of the virus or virus-like particles and/or nanoparticles upon degradation of the polymer matrix.