Recombinant Semliki Forest virus vectors encoding hepatitis B virus small surface and pre-S1 antigens induce broadly reactive neutralizing antibodies.

Most hepatitis B virus (HBV) vaccines consist of viral small surface (S) protein subtype adw2 expressed in yeast cells. In spite of good efficacy, HBV-genotype and subtype differences, escape mutants and insufficient Th1 activation remain potential problems. To address these problems, we generated recombinant Semliki Forest virus (rSFV) vectors encoding S protein, subtype adw2 or ayw2, or a fragment of the large surface protein, amino acids 1-48 of the pre-S1 domain, fused to S (pre-S1.1-48/S). The antigen loop in S protein and the selected pre-S1 sequences are known targets of neutralizing antibodies. BALB/c mice were immunized intravenously with 10(7) rSFV particles and 10(8) rSFV particles 3 weeks later. Antibodies induced by rSFV encoding S proteins reacted preferentially with subtype determinants of yeast-derived S antigen but equally well with patient-derived S antigen. Immunization with rSFV encoding pre-S1.1-48/S resulted in formation of pre-S1- and S-specific immunoglobulin G (IgG), while immunization with the isogenic mutant without S start codon induced pre-S1 antibodies only. Neutralizing antibodies were determined by mixing with plasma-derived HBV/ayw2 and subsequent inoculation of susceptible primary hepatocyte cultures from Tupaia belangeri. S/adw2 antisera neutralized HBV/ayw2 as effectively as antisera raised with S/ayw2. The pre-S1 antibodies also completely neutralized HBV infectivity. The IgG1/IgG2a ratios ranged from 0.28 to 0.88 in the four immunized groups and were lowest for the pre-S1.1-48/S vector, indicating the strongest Th1 response. This vector type may induce subtype-independent and S-escape-resistant neutralizing antibodies against HBV.

Semliki Forest virus biodistribution in tumor-free and 4T1 mammary tumor-bearing mice: a comparison of transgene delivery by recombinant virus particles and naked RNA replicon.

Semliki Forest virus (SFV) vectors are promising tools for cancer gene therapy because they ensure a high level of transgene expression and a rapid and strong cytopathic effect. However, broad tissue tropism and transient expression make it more difficult to develop an optimal cancer treatment strategy. In this study, we have compared the distribution of recombinant SFV particles (recSFV) and naked viral RNA replicon (recRNA) in tumor-free and 4T1 mammary tumor-bearing mice as a consequence of different vector administration strategies. The high potential of SFV recRNA as a biosafe approach for the development of therapeutic treatment was demonstrated. Intravenous (i.v.) inoculation of recRNA provided primary brain targeting in both tumor-free and 4T1 tumor mouse models, but local intratumoral inoculation revealed a high expression level in tumors. Moreover, we observed the predominant tumor targeting of recSFV at a reduced viral dose on i.v. and intraperitoneal (i.p.) virus inoculation, whereas the dose increase led to a broad virus distribution in mice. To prolong transgene expression, we have tested several i.v. and i.p. reinoculation strategies. A detailed evaluation of vector distribution and readministration properties could have an impact on cancer gene therapy clinical trial safety and efficacy.

Behavior of a short preS1 epitope on the surface of hepatitis B core particles.

The major immunodominant region of hepatitis B core particles is widely recognized as the most prospective target for the insertion of foreign epitopes, ensuring their maximal antigenicity and immunogenicity. This region was mapped around amino acid residues 79-81, which were shown by electron cryo-microscopy to be located on the tips of the spikes protruding from the surface of hepatitis B core shells. Here we tried to expose a model sequence, the short immunodominant hepatitis B preS1 epitope 31-DPAFR-35, onto the tip of the spike, with simultaneous deletion of varying stretches from the major immunodominant region of the HBc molecule. Accessibility to the monoclonal anti-preS1 antibody MA18/7 and specific immunogenicity of the preS1 epitope depended on the location and length of the deletion. While chimeras with deletions within the stretch 79-88 presented the preS1 epitope on their surface and demonstrated remarkable preS1 immunogenicity, the corresponding chimeras without any deletion or with a more prolonged deletion (79-93) were unable to provide such presentation and possessed a lower specific preS1 immunogenicity. Deletion of the stretch 79-81 was sufficient to avoid the intrinsic HBc immunogenicity of the core particles, although chimeras with deleted major immunodominant region retained their property to be recognized by human polyclonal or hyperimmune anti-HBc antibodies.

T cell-independent type I antibody response against B cell epitopes expressed repetitively on recombinant virus particles.

Recombinant viral or virus-like particles offer new tools for vaccine development. This study investigated hepatitis B core antigen (HBcAg) capsids and RNA phage Qbeta coats as carriers of a foreign epitope to induce antibody responses in mice. HBcAg capsids were shown to induce T cell-independent (TI) antibodies. We found that these particles behave as antigen-specific TI type 1 (TI-1) Ag comparable to other rigidly structured viruses. When a 5-aa long epitope of the pre-S1 domain of hepatitis B surface antigen (HBsAg) was introduced into the optimal position of the HBc molecule, it also behaved as a TI-1 Ag. Best efficiency of the antibody response to the foreign epitope was achieved by a compensatory deletion after the epitope to retain the regular structure of the HBcAg capsid with a highly repetitive superficial exposition of the foreign epitope. For recombinant Qbeta phage coats, a much more efficient antibody response to the foreign epitope was achieved when the foreign epitope was expressed repetitively on a particulate derivate of Qbeta phage coats. Thus, recombinant virus particles are suitable vaccine carriers for the introduction of foreign B cell epitopes, if precise structural requirements are fulfilled.

Spatial structure and insertion capacity of immunodominant region of hepatitis B core antigen.

Spatial and immunochemical elucidation of hepatitis B core antigen suggested unique organization of its major immunodominant region (MIR) localized within the central part of molecule around amino acid residues 74-83. This superficial loop was recognized as the most prospective target for the insertion of foreign epitopes ensuring maximal antigenicity and immunogenicity of the latter. MIR allowed a substantial capacity of insertions up to about 40 amino acid residues without loss of the capsid-forming ability of core particles. Vector capacity as well as structural behavior and immunological fate of inserted epitopes were dependent on their primary structure. Special sets of display vectors with retained but cross-sectioned MIR as well as with uni- and bidirectionally shortened MIR have been investigated.

Hybrid hepatitis B virus nucleocapsid bearing an immunodominant region from hepatitis B virus surface antigen.

A hepatitis B core antigen (HBcAg) gene bearing the 39-amino-acid-long domain A of hepatitis B surface antigen (HBsAg) within the HBcAg immunodominant loop has been constructed and expressed in Escherichia coli. Chimeric capsids demonstrated HBs but not HBc antigenicity and elicited in mice B-cell and T-cell responses against native HBcAg and HBsAg.