Hepatitis B virus surface antigen assembly function persists when entire transmembrane domains 1 and 3 are replaced by a heterologous transmembrane sequence.

Native hepatitis B surface antigen (HBsAg) spontaneously assembles into 22-nm subviral particles. The particles are lipoprotein micelles, in which HBsAg is believed to span the lipid layer four times. The first two transmembrane domains, TM1 and TM2, are required for particle assembly. We have probed the requirements for particle assembly by replacing the entire first or third TM domain of HBsAg with the transmembrane domain of HIV gp41. We found that either TM domain of HBsAg could be replaced, resulting in HBsAg-gp41 chimeras that formed particles efficiently. HBsAg formed particles even when both TM1 and TM3 were replaced with the gp41 domain. The results indicate remarkable flexibility in HBsAg particle formation and provide a novel way to express heterologous membrane proteins that are anchored to a lipid surface by their own membrane-spanning domain. The membrane-proximal exposed region (MPER) of gp41 is an important target of broadly reactive neutralizing antibodies against HIV-1, and HBsAg-MPER particles may provide a good platform for future vaccine development.

Stable expression of a foreign protein by a replication-competent rubella viral vector.

Live, attenuated rubella vaccine has been used successfully for many years. By expressing additional viral antigens in rubella, we could expand its range and utility as a live, replicating viral vector. Previously, limitations on insert size and stability restricted rubella's ability to express exogenous antigens and immunize against other viruses. In this study, we have overcome this problem by creating a deletion in non-structural protein P150 that makes room for the insert. The resulting rubella hybrid stably expressed a model protein for over 10 passages, while replicating and expressing rubella proteins normally. The foreign protein, GFP, was as large as many important viral antigens, and the virus grew to sufficiently high titers for vaccine use. Further progress in expressing exogenous viral antigens in rubella may produce live viral vectors capable of immunizing against viruses for which attenuation is not currently feasible.

Targeted deletion in the beta20-beta21 loop of HIV envelope glycoprotein gp120 exposes the CD4 binding site for antibody binding.

Different isolates of HIV-1 are known to vary in antibody binding and sensitivity to neutralization. In response to selective pressure, the virus may conceal important neutralizing determinants, such as the CD4 binding site on gp120, through steric hindrance or conformational masking. The 3D structure of gp120 shows five loop structures that surround the CD4 binding site (CD4BS) and may restrict antibody access to the site. We have generated gp120 mutants lacking each of these loops and characterized them with a panel of monoclonal antibodies, including b12 and F105. A targeted deletion in the beta20-beta21 loop resulted in gp120 with enhanced binding of both monoclonals. Enhancement of b12 binding suggests reduced steric hindrance, since the antibody is relatively insensitive to conformation. Enhanced binding of F105, which depends strongly on the protein conformation, suggests that the mutation may allow gp120 to move more freely into the liganded form. The same viral strategies that limit antibody binding may also inhibit antibody induction. Modified forms of gp120, in which the CD4 binding site is more exposed and accessible to antibodies, could provide novel immunogens for eliciting antibodies to this broadly shared neutralizing determinant.

Erythroblast transformation by the friend spleen focus-forming virus is associated with a block in erythropoietin-induced STAT1 phosphorylation and DNA binding and correlates with high expression of the hematopoietic phosphatase SHP-1.

Infection of mice with Friend spleen focus-forming virus (SFFV) results in a multistage erythroleukemia. In the first stage, the SFFV envelope glycoprotein interacts with the erythropoietin receptor and a short form of the receptor tyrosine kinase sf-Stk, resulting in constitutive activation of signal transducing molecules and the development of erythropoietin (Epo)-independent erythroid hyperplasia and polycythemia. The second stage results from the outgrowth of a rare virus-infected erythroid cell that expresses nonphysiological levels of the myeloid transcription factor PU.1. These cells exhibit a differentiation block and can be grown as murine erythroleukemia (MEL) cell lines. In this study, we examined SFFV MEL cells to determine whether their transformed phenotype was associated with a block in the activation of any Epo signal-transducing molecules. Our studies indicate that Epo- or SFFV-induced activation of STAT1/3 DNA binding activity is blocked in SFFV MEL cells. The block is at the level of tyrosine phosphorylation of STAT1, although Jak2 phosphorylation is not blocked in these cells. In contrast to Epo, alpha interferon can induce STAT1 phosphorylation and DNA binding in SFFV MEL cells. The SFFV-transformed cells were shown to express elevated levels of the hematopoietic phosphatase SHP-1, and treatment of the cells with a phosphatase inhibitor restored STAT1 tyrosine phosphorylation. MEL cells derived from Friend murine leukemia virus (MuLV) or ME26 MuLV-infected mice, which do not express PU.1, express lower levels of SHP-1 and are not blocked in STAT1/3 DNA-binding activity. Our studies suggest that SFFV-infected erythroid cells become transformed when differentiation signals activated by STAT1/3 are blocked due to high SHP-1 levels induced by inappropriate expression of the PU.1 protein.

Assembly, structure, and antigenic properties of virus-like particles rich in HIV-1 envelope gp120.

In order to improve the immunogenicity of HIV-1 envelope glycoproteins, we have fused gp120 to a carrier protein, hepatitis B surface antigen (HBsAg), which is capable of spontaneous assembly into virus-like particles. The HBsAg-gp120 hybrid proteins assembled efficiently into 20-30 nm particles. The particles resemble native HBsAg particles in size and density, consistent with a lipid composition of about 25% and a gp120 content of about 100 per particle. Particulate gp120 folds in its native conformation and is biologically active, as shown by high affinity binding of CD4. The particles express conformational determinants targeted by a panel of broadly cross-reactive neutralizing antibodies, and they show tight packing of gp120. Because the particles are lipoprotein micelles, an array of gp120 on their surface closely mimics gp120 on the surface of HIV-1 virions. These gp120-rich particles can enhance the quality, as well as quantity, of antibodies elicited by a gp120 vaccine.