Viroplasms are discrete structures formed in the cytoplasm of rotavirus-infected cells and constitute the replication machinery of the virus. The non-structural proteins NSP2 and NSP5 localize in viroplasms together with other viral proteins, including the polymerase VP1, VP3 and the main inner-core protein, VP2. NSP2 and NSP5 interact with each other, activating NSP5 hyperphosphorylation and the formation of viroplasm-like structures (VLSs). We have used NSP2 and NSP5 fused to the enhanced green fluorescent protein (EGFP) to investigate the localization of both proteins within viroplasms in virus-infected cells, as well as the dynamics of viroplasm formation. The number of viroplasms was shown first to increase and then to decrease with time post-infection, while the area of each one increased, suggesting the occurrence of fusions. The interaction between NSP2 and a series of NSP5 mutants was investigated using two different assays, a yeast two-hybrid system and an in vivo binding/immunoprecipitation assay. Both methods gave comparable results, indicating that the N-terminal region (33 aa) as well as the C-terminal part (aa 131-198) of NSP5 are required for binding to NSP2. When fused to the N and C terminus of EGFP, respectively, these two regions were able to confer the ability to localize in the viroplasm and to form VLSs with NSP2.
A novel method has been developed to study the functional roles of individual vaccinia virus gene products that is neither limited by the possible essentiality of the target gene nor by the availability of conditional lethal mutants. The system utilises the E. coli lac repressor protein, the operator sequence to which it binds and the specific inducer IPTG. It allows the generation of recombinant viruses in which the expression of any chosen gene, and hence virus replication, can be externally controlled. In principle, this system is broadly applicable to the functional analysis of genes in any large DNA virus. This approach has demonstrated that the gene encoding the 14 kDa membrane protein of vaccinia virus is non-essential for the production of infectious intracellular virus particles, but essential for the envelopment of intracellular virions by Golgi membrane and for egress of mature extracellular viral particles. This is the first vaccinia virus protein shown to be specifically required for these processes. In vivo this system may prove useful as a means of attenuating recombinant vaccinia virus vaccines by preventing virus spread without reducing the amount of the foreign antigen expressed in each infected cell. Attenuation of other live virus vaccines may be developed in a similar way.
Cells producing neutralizing monoclonal antibodies (mAbs) to UV-inactivated vaccinia virus strain WR were derived by fusion of hyperimmunized mouse spleen cells with mouse myeloma cells. Three mAbs that reacted strongly with purified virus envelopes as determined by enzyme-linked immunosorbent assay were studied. The three mAbs recognized a 14,000-molecular-weight (14K) envelope protein of vaccinia virus and were shown to be immunoglobulin G2b (mAbC3 and mAbBll) and immunoglobulin M (mAbF11). By using ascites, one of the antibodies, mAbC3, neutralized (50%) virus infectivity with a titer of about 10-4, whereas the others exhibited lower neutralization titers of 10-2 to 10-3. The binding of the mAbs to vaccinia virus did not alter virus attachment to cells. However, virus uncoating was extensively blocked by mAbC3, whereas mAbBll and mAbFll had little or no effect. The three mAbs recognized a similar 14K protein in cowpox, rabbitpox, and vaccinia Elstree strains, indicating a high degree of protein conservation among orthopoxviruses. Based on the binding of mAbs to V-8 protease cleavage products of the 14K protein, the extent of protein recognition for other poxviruses, and differences in the degree of virus neutralization and of virus uncoating into cells, we suggest that the three mAbs recognize different domains of vaccinia 14K viral envelope protein. Furthermore, our findings indicate that the 14K protein may play a role in virus penetration.
The enhancement of recombinant protein expression of a transfected cell line is essential for the development of an efficient large-scale bioprocess. The effect of various media additives and temperature conditions were studied in an attempt to optimize protein production, stability, and protein glycosylation from a Chinese hamster ovary (CHO) cell line producing human beta-interferon (Hu-beta-IFN). We observed a decrease in the ELISA response of the glycoprotein in the later stages of batch cultures, which was attributed to molecular aggregation. Cells were subjected to various concentrations of glycerol, dimethyl sulfoxide (DMSO), and sodium butyrate (NaBu) in a variety of culture systems and conditions. The addition of both NaBu and DMSO resulted in higher specific productivities but reduced growth rates that resulted in a net reduction of interferon produced. Glycerol appeared to stabilize the secreted beta-IFN, resulting in reduced aggregation, despite a decrease in cell growth rate. Glycosylation analysis of isolated beta-IFN showed a time-dependent decrease in sialylation in batch culture that was ameliorated by the presence of glycerol. Low-temperature conditions (30 degrees C) had the greatest effect on productivity with a significant increase in beta-IFN titer as well as a reduction in the degree of molecular aggregation.
The infectious bursal disease virus T=13 viral particle is composed of two major proteins, VP2 and VP3. Here, we show that the molecular basis of the conformational flexibility of the major capsid protein precursor, pVP2, is an amphipatic alpha helix formed by the sequence GFKDIIRAIR. VP2 containing this alpha helix is able to assemble into the T=13 capsid only when expressed as a chimeric protein with an N-terminal His tag. An amphiphilic alpha helix, which acts as a conformational switch, is thus responsible for the inherent structural polymorphism of VP2. The His tag mimics the VP3 C-terminal region closely and acts as a molecular triggering factor. Using cryo-electron microscopy difference imaging, both polypeptide elements were detected on the capsid inner surface. We propose that electrostatic interactions between these two morphogenic elements are transmitted to VP2 to acquire the competent conformations for capsid assembly.
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