On-column refolding and off-column assembly of parvovirus B19 virus-like particles from bacteria-expressed protein.

Virus-like particles (VLPs) are nanometric structures composed of structural components of virions, keeping most of the cellular recognition and internalization properties, but are non-infective as they are deprived of their genetic material. VLPs have been a versatile platform for developing vaccines by carrying their own or heterologous antigenic epitopes. Moreover, VLPs can also be used as nanovessels for encapsulating molecules with therapeutic applications, like enzymes, nucleic acids, and drugs. Parvovirus B19 (B19V) VLPs can be self-assembled in vitro from the denatured major viral particle protein VP2 by equilibrium dialysis. Despite its fair productivity, this process is currently a time-consuming task. Affinity chromatography is used as an efficient step for concentration and purification, but it is only sometimes seen as a method that facilitates the oligomerization of proteins. In this research, we report a novel approach for the in vitro assembly of B19V VLPs through the immobilization of the denatured VP2 into an immobilized metal affinity chromatography (IMAC) column, followed by the on-column folding and the final VLP assembly upon protein elution. This method is suitable for the fast production of B19V VLPs. KEY POINTS: • Biotechnological applications for inclusion bodies • Efficient single-step purification and immobilization strategies • Rapid VLP assembly strategy.

Decoration of virus-like particles with an enzymatic activity of biomedical interest.

The natural properties of virus-like particles (VLPs), like their nanometric size, polyvalence, monodispersity and biocompatibility, had called the attention of scientists from different fields. VLPs constitute an excellent platform for the development nanomaterials with a broad spectrum of applications, ranging from physics of soft matter to the development of vaccines and biological nanocarriers. To expand the repertoire of functions of VLPs, they can be decorated with different molecules. In this research, the α-glucosidase Ima1p of Saccharomyces cerevisiae was attached to the surface of in vitro assembled VLPs of parvovirus B19, by using the SpyTag/SpyCatcher system. The resulting particles were structurally characterized displaying a noticeable increase in size compared to the non-decorated VLPs. The study of the biochemical properties of the coupled enzyme indicate that it increased its Vmax by three-fold toward p-nitrophenyl-α-D-glucopyranoside (p-NPG) as substrate. In addition, the linked enzyme displayed a notorious 10 °C shift in its optimal temperature, from 35 °C for the non-attached enzyme, to 45 °C for the enzyme attached to VLPs. The decorated VLPs were also able to act on glycogen; therefore, these particles may be further developed as part of the therapy for treatment of lysosomal storage diseases derived from defects in the human acid α-glucosidase.