Mapping of immunodominant B-cell epitopes and the human serum albumin-binding site in natural hepatitis B virus surface antigen of defined genosubtype.

Twelve MAbs were generated by immunization of BALB/c mice with plasma-derived hepatitis B virus surface spherical antigen particles subtype ayw2 (HBsAg/ayw2 genotype D). Their epitopes were mapped by analysis of reactivity with plasma-derived HBsAg/ayw2 and HBsAg/adw2 (genotype A) in enzyme immunoassays and blots. Mapping was supported by nested sets of truncated preS2 proteins and preS2 peptides. Five antibodies were S domain-specific, seven were preS2-specific and 11 had a preference for genotype D. According to our data, group I of the three known epitope groups of preS2 has to be divided into IA and IB. Three preS2-specific MAbs forming the new group IA reacted with genotype D residues 3-15 which have not yet been described as an epitope region. IA antibodies strongly inhibited the binding of polymerized human serum albumin. Two antibodies (group II) reacted with the glycosylated N-terminal region of preS2 in plasma-derived HBsAg, but not with a preparation from transfected murine cells. One group III antibody was subtype-specific and reacted with the highly variable preS2 sequence 38-48. Only one antibody (group IB) mapped to the region (old group I) which was believed to be immunodominant and genotype-independent. Geno(sub)type-specific epitopes of preS2 are obviously the immunodominant components of natural HBsAg in BALB/c mice, but these epitopes may be masked by serum albumins in humans. The data may explain why it is difficult to detect anti-preS2 antibodies in human recipients of preS2-containing vaccines, in spite of the preS2 immunodominance in mice.

Fine mapping and functional characterization of two immuno-dominant regions from the preS2 sequence of hepatitis B virus.

A set of monoclonal antibodies (mAbs) directed against the preS2 region of hepatitis B virus (HBV) surface antigen (HBsAg) was generated by immunization of mice with native HBsAg isolated from the blood of HBV carriers. According to (1) mutual competition binding of mAb to natural HBsAg, (2) recognition of full-length preS2 displayed on hepatitis B core particles, (3) recognition of synthetic partial preS2 peptides, and (4) Western blotting using a fusion protein library of truncated preS2 fragments of different legths, mAbs were assigned to two groups which coincided with groups I and III described by Mimms et al. [Virology 1990; 176:604-619]. All mAbs recognized linear epitopes and were glycosylation independent. Six out of eight fine-mapped mAbs recognized common epitopes located in the amino-terminal part of the preS sequence between amino acids 131 and 144 (group I), and inhibited binding of HBsAg to polymerized human serum albumin. Only two mAbs recognized a carboxy-terminal HBV-genotype-specific epitope covering amino acid residues 162 to 168 (group III). These mAbs bound to the highly variable proteolysis-sensitive hinge of preS2. Although four out of six mAbs targeted to immunodominant region I require the full-length sequence 131-L[Q/L]DPRVRGLY[F/L]PAG-144, two mAbs recognize the shorter and slightly carboxy-terminal-shifted sequences 133-DPRVRGLY[F/L]-141 or 135-PVRGLY[F/L]PAG-144. Together with previously identified preS2 epitopes 133-DPRVRGL-139, 137-RGLYFPA-143, and 132-QDPR-135, these data indicate diversity of the immune response against epitopes within the same immunodominant region. This diversity may be generated by a labile secondary structure. Sequence analysis suggests the transition from an alpha-helix to a loop structure at this site.

Analysis of RNA phage fr coat protein assembly by insertion, deletion and substitution mutagenesis.

A structure-function analysis of the icosahedral RNA bacteriophage fr coat protein (CP) assembly was undertaken using linker-insertion, deletion and substitution mutagenesis. Mutations were specifically introduced into either pre-existing or artificially created restriction enzyme sites within fr CP gene expressed in Escherichia coli from a recombinant plasmid. This directs synthesis of wild type protein that undergoes self-assembly and forms capsid-like particles indistinguishable morphologically and immunologically from native phage particles. A series of fr CP variants containing sequence alterations in the regions which are (i) exposed on the external surface of capsid or (ii) located on the contacting areas between CP subunits were obtained and their assembly properties investigated. The majority of mutants demonstrated reduction of assembly ability and formed either CP dimers (mutations at residues 2, 10, 63 or 129) or both dimer and capsid structures (residue 2 or 69). The exceptions were variants demonstrating normal assembly and containing insertions at residues 2, 50 or 129 of the fr CP. A third type of assembled structure was formed by a variant with a single amino acid substitution I104T. The alpha A-helix region (residues 97-111) is particularly sensitive to mutation and any alteration in this region decreases accumulation of mutant protein in E. coli. The relative contributions of particular fr CP domains in maintenance of capsid structural integrity as well as the possible capsid assembly mechanism are discussed.

Tetrapeptide QDPR is a minimal immunodominant epitope within the preS2 domain of hepatitis B virus.

A hepatitis B virus preS2 deletion library with the preS2 sequence fused to the coat protein of the RNA phage fr (fr CP) as a carrier has been constructed and used for the approximate localization of epitope recognized by a panel of murine monoclonal anti-preS2 antibodies. DNA copies of putative preS2 epitopes were synthesized and cloned within the fr CP gene. Tetrapeptide Gln-Asp-Pro-Arg (QDPR) corresponding to the preS (132-135) sequence was found to be the minimal sufficient recognition site for one of the monoclonal antibodies, S26. The closely related tetrapeptide EDPR did not mimic the epitope activity of QDPR.

Determination of the minimal length of preS1 epitope recognized by a monoclonal antibody which inhibits attachment of hepatitis B virus to hepatocytes.

The minimal amino acid sequence sufficient to be recognized efficiently by virus-attachment inhibiting murine monoclonal anti-preS1 antibody MA18/7 has been determined. We have constructed a recombinant gene library using the cloned coat protein gene of Escherichia coli RNA bacteriophage fr as a carrier. Different fragments of preS1 region from cloned hepatitis B virus (HBV) genomes, subtype ayw and adw, were inserted at position 2 of the 129 amino acid-long fr coat protein gene in the appropriate E. coli expression vectors. Fine mapping of preS1 epitope recognized by MA18/7 was accomplished by bidirectional shortening of the preS1 within original recombinant preS-fr coat protein genes with Bal31 exonuclease. Immunoblot analysis of the obtained recombinant protein library revealed that the tetrapeptide Asp-Pro-Ala-Phe (DPAF), located at the position preS(31-34) and conserved in all known HBV genomes, is sufficient to bind MA18/7 antibody. Recognition of the preS1 region by MA18/7 occurred irrespective of the amino acid context surrounding this DPAF tetrapeptide. Further shortening of this minimal epitope from the left or from the right side completely prevented antibody binding in immunoblots.