A hydrophobic domain in the large envelope protein is essential for fusion of duck hepatitis B virus at the late endosome.

The duck hepatitis B virus (DHBV) envelope is comprised of two transmembrane (TM) proteins, the large (L) and the small (S), that assemble into virions and subviral particles. Secondary-structure predictions indicate that L and S have three alpha-helical, membrane-spanning domains, with TM1 predicted to act as the fusion peptide following endocytosis of DHBV into the hepatocyte. We used bafilomycin A1 during infection of primary duck hepatocytes to show that DHBV must be trafficked from the early to the late endosome for fusion to occur. Alanine substitution mutations in TM1 of L and S, which lowered TM1 hydrophobicity, were used to examine the role of TM1 in infectivity. The high hydrophobicity of the TM1 domain of L, but not of S, was shown to be essential for virus infection at a step downstream of receptor binding and virus internalization. Using wild-type and mutant synthetic peptides, we demonstrate that the hydrophobicity of this domain is required for the aggregation and the lipid mixing of phospholipid vesicles, supporting the role of TM1 as the fusion peptide. While lipid mixing occurred at pH 7, the kinetics of insertion of the fusion peptide was increased at pH 5, consistent with the location of DHBV in the late-endosome compartment and previous studies of the nonessential role of low pH for infectivity. Exchange of the TM1 of DHBV with that of hepatitis B virus yielded functional, infectious DHBV particles, suggesting that TM1 of all of the hepadnaviruses act similarly in the fusion mechanism.

A metastable form of the large envelope protein of duck hepatitis B virus: low-pH release results in a transition to a hydrophobic, potentially fusogenic conformation.

We have examined the structure and fusion potential of the duck hepatitis B virus (DHBV) envelope proteins by treating subviral particles with deforming agents known to release envelope proteins of viruses from a metastable to a fusion-active state. Exposure of DHBV particles to low pH triggered a major structural change in the large envelope protein (L), resulting in exposure of trypsin sites within its S domain but without affecting the same region in the small surface protein (S) subunits. This conformational change was associated with increased hydrophobicity of the particle surface, most likely arising from surface exposure of the hydrophobic first transmembrane domain (TM1). In the hydrophobic conformation, DHBV particles were able to bind to liposomes and intact cells, while in their absence these particles aggregated, resulting in viral inactivation. These results suggests that some L molecules are in a spring-loaded metastable state which, when released, exposes a previously hidden hydrophobic domain, a transition potentially representing the fusion-active state of the envelope.

Hepadnavirus envelope topology: insertion of a loop region in the membrane and role of S in L protein translocation.

A unique feature of the large hepadnavirus envelope protein (L) is its mixed transmembrane topology, resulting from partial posttranslational translocation of the pre-S domain. Using protease protection analysis, we demonstrate for duck hepatitis B virus an essential role for the small envelope protein (S) in this process, providing the first experimental evidence for an S translocation channel. Further analysis revealed that the presumed cytoplasmic loop between TM1 and TM2 in the C-terminal S domain is membrane embedded and protrudes to the particle surface. These data suggest that some L molecules form a highly folded, potentially spring-loaded topology with five membrane-spanning regions and a membrane-traversing pre-S chain.

Normal phosphorylation of duck hepatitis B virus L protein is dispensable for infectivity.

A fraction of the large surface protein (L) of duck hepatitis B virus (DHBV) is phosphorylated at serine or threonine residues (E. Grgacic & D. Anderson, Journal of Virology 68, 7344-7350, 1994). We now report the identification of phosphorylation sites in DHBV L protein. Using site-directed mutagenesis, we have identified serine-118 (S118) as the major phosphorylation site, accepting approximately 64% of the total phosphate groups incorporated in L, and resulting in retarded migration of phosphorylated L in SDS-PAGE. Proline-119 is indispensable for S118 phosphorylation. Mutation of other serine/threonine residues which are followed by prolines (T79, T89, S117 and T155) together with S118 further reduced phosphorylation to around 19% of wild-type. Non-equilibrium pH gel electrophoresis (NEPHGE) and SDS-PAGE of 33P-labelled L protein revealed two phosphorylated L species, while protein with the S118 to alanine mutation was detected as only one labelled species, consistent with multiple phosphorylations in wild-type L. Together, these results demonstrate that serine 118 is the major phosphorylation site for a proline-directed kinase, and that a proportion of L molecules are additionally phosphorylated at one of a number of secondary sites. DHBV mutants encoding L proteins with minimal phosphorylation (alanine mutants) or mimicking constitutive phosphorylation (aspartic acid mutants) remained infectious both in cell culture and in ducks, demonstrating that L phosphorylation may play only a minor role in DHBV replication.

Quantification of infectious duck hepatitis B virus by radioimmunofocus assay.

A simple method is described for the precise quantification of infectious duck hepatitis B virus (DHBV) in cell culture, using a radioimmunofocus assay (RIFA). Primary duck hepatocyte cell cultures were infected with serial dilutions of viral samples as for a plaque assay, but then maintained with liquid overlay medium. After incubation for up to 14 days, cell monolayers were fixed with acetone, then stained with a monoclonal antibody to DHBV L protein followed by secondary antibody labelled with 125I. Foci of infection (representing individual infectious particles in the inoculum) were detected by autoradiography. The number of foci recovered was increased by addition of dimethyl sulphoxide to culture medium, but was not appreciably altered by the use of semi-solid medium. The titre of virus suspensions determined by RIFA correlated well with titration in ducklings. The RIFA is a useful method for titration of DHBV, as it has a wide dynamic range and is well suited to parallel titration of large numbers of samples. This assay will have wide use for the analysis of DHBV growth kinetics, antiviral efficacy, and virus inactivation procedures.

The large surface protein of duck hepatitis B virus is phosphorylated in the pre-S domain.

The two major envelope proteins (large [L] and small [S]) of duck hepatitis B virus are encoded by the pre-S/S open reading frame. The L protein is initiated from the AUG at position 801 in the pre-S region of the pre-S/S coding sequence, yielding an N-terminal consensus sequence for myristylation. Western immunoblots of the L protein often reveal a doublet at 36 and 35 kDa, with the latter attributed to the use of one of the three internal initiation codons. However, metabolic labelling with [3H]myristic acid results in labelling of both P35 and P36, indicating that both species must be initiated from the same start codon. Using metabolic labelling with 32P and digestion with residue-specific phosphatases, we demonstrate that L protein heterogeneity is due to phosphorylation of threonine and/or serine residues within the pre-S domain. We propose that at least one possible phosphorylation site is located at a novel (S/T)PPL motif which is conserved near the carboxyl end of the pre-S1 domain in all hepadnavirus sequences. Two to three additional (S/T)P motifs are also present in the carboxyl half of the pre-S1 (but not pre-S2 or S) domain of all hepadnaviruses. L protein in serum-derived particles is resistant to phosphatase digestion in the absence of detergents, reflecting an internal disposition of the phosphorylated pre-S domain and suggesting a role for dephosphorylation in the topological shift within L during morphogenesis (P. Ostapchuk, P. Hearing, and D. Ganem, EMBO J. 13:1048-1057, 1994). Furthermore, we observe that the relative amount of the phosphorylated form of L increases with time in the viral growth cycle. These findings imply that phosphorylation-dephosphorylation of the L protein is an important, regulated mechanism necessary for correct virion morphogenesis.

Electroimmunoblotting of myelin basic protein peptides: a novel approach to the rapid characterisation of antigenic specificities of monoclonal and polyclonal anti-MBP antibodies.

A rapid and sensitive method for the identification of antigenic determinants recognised by monoclonal and polyclonal antibodies directed against myelin basic protein (MBP) is described. By electroimmunoblotting a series of overlapping peptides covering the entire MBP molecule with monoclonal anti-MBP antibodies, the binding pattern of immunoreactive peptides can be rapidly determined and the reactive antigenic determinant identified. This procedure, which can be performed with both native and synthetic peptides, can also with appropriate modification, be applied to the analysis of naturally occurring or experimentally induced polyclonal anti-MBP autoantibodies.

Rapid characterization of protein epitopes recognized by monoclonal antibodies using direct probing on thin-layer and paper chromatograms.

A simple method for the comparison and identification of protein epitopes recognized by monoclonal antibodies directly on thin-layer plates and 3MM paper chromatograms is described. Enzyme digests of myelin basic protein were separated on thin-layer plates and 3MM paper, fixed with glutaraldehyde and probed directly with affinity-purified mouse monoclonal antibodies. Detection of the immunoreactive peptides was enhanced using a second rabbit anti-mouse immunoglobulin and finally located using an alkaline phosphatase-conjugated anti-rabbit immunoglobulin. By probing the same enzyme digests of MBP with various monoclonal antibodies raised against MBP, a different binding 'pattern' of reactive peptides is rapidly obtained for monoclonal antibodies of differing specificities. This procedure was extended to the identification of the antigenic determinant using synthetic peptides. The major advantages of this procedure are its simplicity, non-radioactive nature and speed. Furthermore, there is the possibility of sequencing immunoreactive peptides eluted from the 3MM paper.