Finger printing human norovirus-like particles by capillary isoelectric focusing with whole column imaging detection.

Owing to the limitation of in vitro culture of human noroviruses (HuNoVs), the development of HuNoV vaccines has to depend on the self-assembling virus-like particles (VLPs) with capsid protein expression. The heterogeneity of artificial VLPs exert an impact on the immunogenicity, and should be considered as one of the factors in vaccine evaluation. In this study, we biochemically finger print the HuNoV VLPs with different genogroups, genotypes and sub-genotypes which constitute for a candidate vaccine, by using capillary isoelectric focusing with whole column imaging detection (cIEF-WCID). The electropherograms of GI.1, GII.3, GII.4 and GII.17 VLPs in fluorescence signal were described in the monomer VP1 forms after degenerated by 8 M urea. The four HuNoV VLPs showed different properties in electropherogram finger prints. The finger prints were also reproducible within a certain concentration range (approx. 150 ∼ 20 ug/ml). This method can also tell the changes of pI finger-print patterns when the expired HoNoV VLPs were tested. In conclusion, cIEF-WCID shows great promise for evaluating the production consistency of HuNoV VLP vaccine.

Simultaneous refolding of denatured PsbS and reconstitution with LHCII into liposomes of thylakoid lipids.

The thylakoid membrane protein PsbS is critical for quenching excessive excitation energy in mechanisms that involve the light-harvesting complexes of photosystem II. Liposomes of thylakoid lipids have been shown to be a very good platform to study photosynthetic membrane proteins and their interactions. In this study, we simultaneously refolded and reconstituted functional pea PsbS into liposomes of thylakoid lipids starting from denatured expressed protein. Intrinsic fluorescence spectroscopy, trypsin digestion, and circular dichroism spectroscopy were used to characterize the native state of PsbS in the proteoliposomes. The functionality of refolded PsbS was further demonstrated by its effect on the fluorescence quenching of the major antenna system of photosystem II (LHCII) co-inserted into the liposomes. The fluorescence yield of native trimeric LHCII was lowered by PsbS by 50% at neutral pH and by a further 25% upon lowering the pH to 4.5. Furthermore, the acid-induced fluorescence reduction was completely reversed by addition of N,N'-dicyclohexylcarbodiimide, an inhibitor of protein protonation. These results indicate that reconstituted PsbS induces strong quenching of LHCII sensing changes in local pH via its protonation sites.