Embodiments described herein provide orthohepadnavirus capsid protein (Cp) heterodimers, bicistronic vectors encoding the heterodimers, and methods for producing the heterodimers. The heterodimers can be used to form mosaic virus-like particles. In certain embodiments, the heterodimers can form a hexamer, which in turn can be used to nucleate capsid formation, resulting in a Janus particle-like virus-like particle. The hexamer's can then be removed, leaving holey capsids. The capsids can be loaded with, for example, one or more polypeptides, small molecules, or a combination of polypeptides and small molecules. The holes of the holey capsids can be filled with another orthohepadnavirus heterodimer or a homodimer.

Genetically modified HBc polypeptides are provided.

The present invention relates to a recombinant self-assembled protein comprising a target-oriented peptide and a use thereof. The recombinant self-assembled protein according to the present invention, comprising a target-oriented peptide, does not require an additional process for providing target-orientedness, and is thus capable of delivering a desired drug to a target tissue or target cell without using additives, such as chemical binders or stabilizers; therefore, the protein can be used for photothermal therapy, drug delivery, imaging, or the like. In particular, according to the present invention, it is possible to prepare gold-protein nanoparticle fusions in which uniform high-density gold nanoparticles having target-orientedness are bound to protein surfaces, without an additional process of surface stabilization or process for providing target-orientedness. Compared with conventional gold nanoparticles, the gold-protein nanoparticle fusions according to the present invention show structural stability against pH variation and concentration variation, and also have excellent target-orientedness; therefore, the fusions can bring a dramatic enhancement to the utilization of gold nanoparticles in photothermal therapy.

Genetically modified HBc polypeptides are provided.

The present invention relates to a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body for magnetic resonance imaging and magnetic thermotherapy. According to the present invention, a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body which has target directionality and a high density of ultrafine gold nanoparticles uniformly coupled to the surface of protein nanoparticles can be fabricated with neither a separate surface stabilization process nor a separate target directionality conferring process. Hence, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention is superior to conventional gold nanoparticles in terms of biocompatibility and has excellent target directionality as well as being identified to have a temperature elevation potential in an alternating magnetic field and a functionality as a T2-MRI contrast medium thanks to the superparamagnetism property of the ultrafine gold nanoparticles.

The invention is directed to compositions and methods for the stabilization of viral and bacterial vaccines. Vaccines of the invention are contained in VLPs with stabilizing agents such as, for example, sugar alcohols (e.g., sorbitol) and degraded gelatins. Preferably the gelatin has an average molecular weight of 10,000 kilodaltons or less. These vaccines have a substantially improved thermostability as well as long term stability. The invention is also directed to the manufacture of a vaccine or the invention and methods for the administration of a vaccine of the invention to patients.

The invention is directed to compositions and methods for the stabilization of viral and bacterial vaccines. Vaccines of the invention are contained in VLPs with stabilizing agents such as, for example, sugar alcohols (e.g., sorbitol) and degraded gelatins. Preferably the gelatin has an average molecular weight of 10,000 kilodaltons or less. These vaccines have a substantially improved thermostability as well as long term stability. The invention is also directed to the manufacture of a vaccine or the invention and methods for the administration of a vaccine of the invention to patients.

Genetically modified HBc polypeptides are provided.

The present invention relates to a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body for magnetic resonance imaging and magnetic thermotherapy. According to the present invention, a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body which has target directionality and a high density of ultrafine gold nanoparticles uniformly coupled to the surface of protein nanoparticles can be fabricated with neither a separate surface stabilization process nor a separate target directionality conferring process. Hence, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention is superior to conventional gold nanoparticles in terms of biocompatibility and has excellent target directionality as well as being identified to have a temperature elevation potential in an alternating magnetic field and a functionality as a T2-MRI contrast medium thanks to the superparamagnetism property of the ultrafine gold nanoparticles. Therefore, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention can be utilized as a core technology in the fields of magnetic thermotherapy and magnetic resonance imaging contrast media.

The invention is directed to compositions and methods for the stabilization of viral and bacterial vaccines. Vaccines of the invention are contained in VLPs with stabilizing agents such as, for example, sugar alcohols (e.g., sorbitol) and degraded gelatins. Preferably the gelatin has an average molecular weight of 10,000 kilodaltons or less. These vaccines have a substantially improved thermostability as well as long term stability. The invention is also directed to the manufacture of a vaccine or the invention and methods for the administration of a vaccine of the invention to patients.