Mutational analysis of hepatitis B surface antigen particle assembly and secretion

Phosphorylation-dependent binding of hepatitis B virus core particles to the nuclear pore complex

Although many viruses replicate in the nucleus, little is known about the processes involved in the nuclear import of viral genomes. We show here that in vitro generated core particles of human hepatitis B virus bind to nuclear pore complexes (NPCs) in digitonin-permeabilized mammalian cells. This only occurred if the cores contained phosphorylated core proteins. Binding was inhibited by wheat germ agglutinin, by antinuclear pore complex antibodies, and by peptides corresponding either to classical nuclear localization signals (NLS) or to COOH-terminal sequences of the core protein. Binding was dependent on the nuclear transport factors importins (karyopherins) alpha and beta. The results suggested that phosphorylation induces exposure of NLS in the COOH-terminal portion of the core protein that allows core binding to the NPCs by the importin- (karyopherin-) mediated pathway. Thus, phosphorylation of the core protein emerged as an important step in the viral replication cycle necessary for transport of the viral genome to the nucleus.

Mutations in the carboxyl-terminal domain of the small hepatitis B virus envelope protein impair the assembly of hepatitis delta virus particles

The carboxyl-terminal domain of the small (S) envelope protein of hepatitis B virus was subjected to mutagenesis to identify sequences important for the envelopment of the nucleocapsid during morphogenesis of hepatitis delta virus (HDV) virions. The mutations consisted of carboxyl-terminal truncations of 4 to 64 amino acid residues and small combined deletions and insertions spanning the entire hydrophobic domain between residues 163 and 224. Truncation of as few as 14 residues partially inhibited glycosylation and secretion of S and prevented assembly or stability of HDV virions. Short internal combined deletions and insertions were tolerated for secretion of subviral particles with the exceptions of those affecting residues 164 to 173 and 219 to 223. However, mutants competent for subviral particle secretion had a reduced capacity for HDV assembly compared to that of the wild type. One exception was a mutant carrying a deletion of residues 214 to 218, which exhibited a twofold increase in HDV assembly (or stability), whereas deletions of residues 179 to 183, 194 to 198, and 199 to 203 were the most inhibitory. Substitutions of single amino acids between residues 194 and 198 demonstrated that HDV assembly deficiency could be assigned to the replacement of the tryptophan residue at position 196. We concluded that assembly of stable HDV particles requires a specific function of the carboxyl terminus of S which is mediated at least in part by Trp-196.

YMDD motif in hepatitis B virus DNA polymerase influences on replication and lamivudine resistance: A study by in vitro full-length viral DNA transfection

Recently, lamivudine used to treat patients with hepatitis B virus (HBV) infection was revealed to have potent antiviral activity. However, HBV resistance to lamivudine has been reported and shown to have amino acid substitutions in the methionine residue of the conserved tyrosine (Y), methionine (M), aspartate (D), aspartate (D) motif of RNA-dependent DNA polymerase. To explore the consequences of substitutions in this motif (YMDD), we made 7 variants by substituting the methionine of the YMDD motif with isoleucine (I), valine (V), alanine (A), leucine (L), lysine (K), arginine (R), and threonine (T). Replication ability of these variants was evaluated by transfection into human hepatoma cells. Sensitivity to lamivudine was tested for replication-competent variants. Four variants with hydrophobic substitutions (I, V, A, and L) remained replication-competent, whereas 3 others with hydrophilic substitutions (K, R, and T) exhibited impaired replication. Of the 4 replication-competent variants, 2 (I and V) were resistant, and 2 (A and L) were sensitive to lamivudine. Because the polymerase and the surface gene overlap, the introduction of these mutations affected the secretion of hepatitis B surface antigen (HBsAg), namely 4 variants (I, V, L, and R) secreted HBsAg, whereas 3 variants (A, K, and T) did not. Our study elucidated that only one amino acid substitution in the YMDD motif was sufficient to cause lamivudine resistance in vitro. As a result of replication competence and lamivudine sensitivity, only viruses having YIDD or YVDD sequences may appear during treatment with lamivudine. This in vitro system could be used to study HBV mutations, replication competence, and their susceptibility to antivirals.

Use of a prenylation inhibitor as a novel antiviral agent

No specific therapy exists for hepatitis delta virus (HDV), which can cause severe liver disease. Molecular genetic studies have implicated the prenylation site of large delta antigen as a critical determinant of HDV particle assembly. We have established a cell culture model which produces HDV-like particles, and we show that delta antigen prenylation can be pharmacologically inhibited by the prenylation inhibitor BZA-5B. Furthermore, BZA-5B specifically abolishes particle production in a dose-dependent manner. These results demonstrate that the use of such a prenylation inhibitor-based antiviral therapy may be feasible and identify a novel class of potential antiviral agents.

Sodium dodecylsulfate polyacrylamide gel electrophoresis of recombinant hepatitis B surface antigen particles

To investigate the factors leading to broadening of the recombinant hepatitis B surface antigen (HBsAg) peak in size-exclusion chromatography, the HBsAg particles eluting in different regions of the peak were subjected here to electrophoretic analysis. In nonreduced samples, the 24-kD band corresponding to the S monomer was detected when excessively large amounts of HBsAg were loaded onto the gel. Hence, some monomers are not disulfide-crosslinked in assembled particles. On the other hand, the results of alkylation experiments indicated the presence of free sulfhydryl group(s) in a little portion of freshly-purified HBsAg which was retarded on the size-exclusion chromatographic column and had significant antigenicity. This fraction of HBsAg was shown to be oligomeric and capable of spontaneous assembly into higher-order structures during aging.

Intracellular retention of duck hepatitis B virus large surface protein is independent of preS topology

The mechanism of intracellular retention for the large surface protein (L) of duck hepatitis B virus (DHBV) was analyzed by examination of the transmembrane topologies and secretory properties of a collection of DHBV L mutants and compared with that of human hepatitis B virus (HBV) L. Our results demonstrate that, in contrast to its HBV counterpart, intracellular retention of DHBV L does not depend on the cytosolic disposition of its preS domain. L mutants with either cytosolic or lumenal preS were mostly retained in the absence of the small surface protein (S), whereas coexpression with S resulted in efficient secretion of both topological forms. Coexpression of the wild-type DHBV L with S resulted in efficient incorporation of L into secreted S + L particles, whereas HBV L was partially excluded from secreted particles under the same conditions. We propose that HBV provides L retention even in the presence of an excess of S, by exclusion of molecules with cytosolic preS domains from secreted particles at the stage of their assembly. DHBV lacks such a retention mechanism due to the absence of topological selection in particulate assembly.

A short linear sequence in the pre-S domain of the large hepatitis B virus envelope protein required for virion formation

Envelopment of the hepatitis B virus (HBV) nucleocapsid depends on the large envelope protein L, which is expressed as a transmembrane polypeptide at the endoplasmic reticulum membrane. Previous studies demonstrated that the cytosolic exposure of the N-terminal pre-S domain (174 amino acids) of L was required for virion formation. N-terminal truncations of L up to Arg 103 were tolerated. To map sites in the remaining C-terminal part of pre-S important for virion morphogenesis, a series of 11 L mutants with linker substitutions between Asn 98 and Pro 171 was generated. The mutants formed stable proteins and were secreted in transfected cell cultures, probably as components of subviral hepatitis B surface antigen particles. All four constructs with mutations between Asn 98 and Thr 125 were unable to complement in trans the block in virion formation of an L-negative HBV genome in cotransfected HuH7 cells. These mutants had a transdominant negative effect on virus yield in cotransfections with the wild-type HBV genome. In contrast, all seven mutants with substitutions downstream of Ser 124 were able to envelop the nucleocapsid and to secrete HBV. The sequence between Arg 103 and Ser 124 is highly conserved among different HBV isolates and also between HBV and the woodchuck hepatitis virus. Point mutations in this region introducing alanine residues at conserved positions blocked virion formation, in contrast to mutations at nonconserved residues. These results demonstrate that the pre-S sequence between Arg 103 and Ser 124 has an important function in HBV morphogenesis.

Expression of a human cytomegalovirus gp58 antigenic domain fused to the hepatitis B virus nucleocapsid protein

Hepatitis B virus core antigen (HBcAg) has been used as a carrier for expression and presentation of a variety of heterologous viral epitopes in particulate form. The aim of this study was to produce hybrid antigens comprising HBcAg and an immunogenic epitope of human cytomegalovirus (HCMV). A direct comparison was made of amino and carboxyl terminal fusions in order to investigate the influence of position of the foreign epitope on hybrid core particle formation, antigenicity and immunogenicity. HCMV DNA encoding a neutralising epitope of the surface glycoprotein gp58 was either inserted at the amino terminus or fused to the truncated carboxyl terminus of HBcAg and expressed in Escherichia coli. The carboxyl terminal fusion (HBc3-144-HCMV) was expressed at high levels and assembled into core like particles resembling native HBcAg. Protein with a similar fusion at the amino terminus (HCMV-HBc1-183) could not be purified or characterised immunologically, although it formed core like particles. HBc3-144-HCMV displayed HBc antigenicity but HCMV antigenicity could not be detected by radioimmunoassay or western blotting using anti-HCMV monoclonal antibody 7-17 or an anti-HCMV human polyclonal antiserum. Following immunisation of rabbits with HBc3-144-HCMV, a high titre of anti-HBc specific antibody was produced along with lower titres of HCMV/gp58 specific antibody.

Characterization of early hepatitis B virus surface protein oligomers

The small surface protein (S) of the hepatitis B virus (HBV) is synthesized as unglycosylated p24 and N-glycosylated gp27 and forms disulfide linked dimers. Former models proposed that these complexes consist preferentially of p24-gp27 heterodimers. Furthermore, cell free in vitro experiments suggested that p24 has a transmembrane topology different from gp27. We tested these models by expressing the HBV surface proteins in transfected cell cultures and characterizing early maturation products after short pulse labelings. Two dimensional unreduced-reduced polyacrylamide gel electrophoresis demonstrated that p24 and gp27 dimerized without preference for a specific pairing. Protease protection experiments showed that both, p24 and gp27, had identical transmembrane topologies in cell culture. The middle sized (M) and large HBV surface proteins formed mixed dimers with the S protein. Mutant M and S protein in which all 10 cysteine residues in the ectodomain and transmembrane regions were replaced by serine residues formed no intermolecular S-S bridges but were secreted like wild type M and S protein.

Hepatitis B virus nucleocapsid envelopment does not occur without genomic DNA synthesis

Assembly of the enveloped hepatitis B virus (HBV) is initiated by packaging of the RNA pregenome and the viral reverse transcriptase-DNA polymerase into a nucleocapsid. The pregenome is then reverse transcribed into single-stranded minus-polarity DNA, which is subsequently replicated to double-stranded DNA. All replicative intermediates are observable in capsids within infected liver, but only relatively mature nucleocapsids containing partially double stranded DNA are found in secreted virions. This observation suggests that maturation of the genome within the capsid is required for envelopment and secretion. We show that the differential distribution of replicative intermediates between intracellular nucleocapsids and secreted virions is also observable in human hepatoma cells transfected with wild-type HBV genomes. However, nucleocapsids were not enveloped or secreted when they were produced by an HBV genome carrying a missense mutation in the DNA polymerase that eliminates all DNA synthesis. An HBV missense mutant defective in the RNase H activity of the polymerase which allowed minus-strand DNA synthesis but not formation of double-stranded DNA was able to form virion-like particles. These experiments demonstrate that immature nucleocapsids containing pregenomic RNA are incompetent for envelopment and that minus-strand DNA synthesis in the interior lumen of the capsid is coupled to the appearance of a signal on the exterior of the nucleocapsid that is essential for its envelopment.

Functions of the internal pre-S domain of the large surface protein in hepatitis B virus particle morphogenesis

The large hepatitis B virus (HBV) surface protein (L) forms two isomers which display their N-terminal pre-S domain at the internal and external side of the viral envelope, respectively. The external pre-S domain has been implicated in binding to a virus receptor. To investigate functions of the internal pre-S domain, a secretion signal sequence was fused to the N terminus of L (sigL), causing exclusive expression of external pre-S domains. A fusion construct with a nonfunctional signal (s25L), which corresponds in its primary sequence to sigL cleaved by signal peptidase, was used as a control. SigL was N glycosylated in transfected COS cells at both potential sites in pre-S in contrast to s25L or wild-type L, confirming the expected transmembrane topologies of sigL and s25L. Phenotypic characterization revealed the following points. (i) SigL lost the inhibitory effect of L or s25L on secretion of subviral hepatitis B surface antigen particles, suggesting that the retention signal mapped to the N terminus of L is recognized in the cytosol and not in the lumen of the endoplasmic reticulum. (ii) SigL was secreted into the culture medium even in the absence of the major HBV surface protein (S), while release of an L mutant lacking the retention signal was still dependent on S coexpression. (iii) s25L but not sigL could complement an L-negative HBV genome defective for virion secretion in cotransfections. This suggests that the cytosolic pre-S domain, like a matrix protein, is involved in the interaction of the viral envelope with preformed cytosolic nucleocapsids during virion assembly.

Phenotypic mixing of rodent but not avian hepadnavirus surface proteins into human hepatitis B virus particles

The virus family Hepadnaviridae comprises two genera: orthohepadnaviruses isolated from humans (hepatitis B virus [HBV]) and rodents (e.g., woodchuck hepatitis virus [WHV]) and avihepadnaviruses isolated from birds (e.g., duck hepatitis B virus [DHBV]). They carry in their envelopes two (DHBV) or three (HBV and WHV) coterminal proteins referred to as small (S), middle (M), or large (L) surface protein. These proteins are also secreted from infected cells as subviral particles consisting of surface protein and lipid (e.g., 20-nm hepatitis B surface antigen for HBV). To investigate the assembly of these proteins, we asked whether surface proteins from different hepadnaviruses are able to mix phenotypically with each other. By coexpression and coimmunoprecipitation with species-specific antibodies, we could show the formation of mixed subviral particles and disulfide-linked heterodimers between the WHV S and HBV M proteins whereas the DHBV and HBV surface proteins did not coassemble. Complementation of HBV genomes defective in expressing the S or L protein and therefore incompetent to form virions was possible with the closely related WHV S protein or a WHV pre-S-HBV S chimera, respectively, but not with the less related DHBV S or L protein or with a DHBV L-HBV S chimera. The results suggest that the assembly of HBV subviral particles and virion envelopes requires relatively precise molecular interactions of their surface proteins, which are not conserved between the two hepadnavirus genera. This contrasts with the ability of, e.g., rhabdoviruses or retroviruses, to incorporate envelope proteins even from unrelated viruses.

Post-translational alterations in transmembrane topology of the hepatitis B virus large envelope protein

The preS domain at the N-terminus of the large envelope protein (LHBs) of the hepatitis B virus is involved in (i) envelopment of viral nucleocapsids and (ii) binding to the host cell. While the first function suggests a cytosolic location of the preS domain during virion assembly, the function as an attachment site requires its translocation across the lipid bilayer and final exposure on the virion surface. We compared the transmembrane topology of newly synthesized LHBs in the endoplasmic reticulum (ER) membrane with its topology in the envelope of secreted virions. Protease sensitivity and the absence of glycosylation suggest that the entire preS domain of newly synthesized LHBs remains at the cytosolic side of ER vesicles. However, virions secreted from transfected cell cultures or isolated from the blood of persistent virus carriers expose antibody binding sites and proteolytic cleavage sites of the preS domain at their surface in approximately half of the LHBs molecules. Thus, preS domains appear to be transported across the viral lipid barrier by a novel post-translational translocation mechanism to fulfil a dual function in virion assembly and attachment to the host cell.

Site-directed mutagenesis of cysteine residues of hepatitis B surface antigen. Analysis of two single mutants and the double mutant

The structure of hepatitis B surface antigen (HBsAg) is mainly maintained by an intricate disulfide network responsible for most of its structural and antigenic properties. Characterization of three cysteine-replacement mutants of HBsAg has been performed by both structural and immunological methods. Replacement of Cys121 or Cys124 with serine results in mutant proteins that show diminished binding titres to both monoclonal antibodies and to a polyclonal serum, indicating that a structural change has taken place. Circular dichroism analysis shows that the substitution of either of these two residues also diminishes the helical content of the protein. However, the double mutant, in which both cysteine residues have been simultaneously changed, reverts the properties of the single mutations, and shows similar behaviour to the wild-type protein. Both the single and double cysteine mutants are efficiently glycosylated and secreted from Chinese hamster ovary cells and, in all cases, the mutant proteins assemble into spherical particles of similar buoyant density to both the wild-type and serum derived HBsAg.

Mapping a region of the large envelope protein required for hepatitis B virion maturation

The hepatitis B virion is a spherical double-shelled particle carrying three surface proteins (large [L], middle [M], and small [S]) in its envelope. All three proteins are translated from a single open reading frame by means of three different in-frame start codons from unspliced mRNAs. This organization defines three protein domains (pre-S1, pre-S2, and S). All three domains together form the L protein, whereas the M protein consists of domains pre-S2 plus S. The L and S proteins are both necessary for virion production, whereas the M protein is dispensable, suggesting an important function of the pre-S1 domain in virion morphogenesis. To investigate this point, we created a series of N-terminal-truncated L mutants and tested their ability to substitute for the wild-type L protein in virion formation. We found that the constructs fell into two classes, (i) N-terminal deletion mutants lacking up to 102 of the 119 amino acids of the pre-S1 domain still allowed virion maturation, showing that the N-terminal 5/6 of the pre-S1 sequence is dispensable for this process. (ii) Mutants lacking 110 or more N-terminal amino acids were unable to substitute for the L protein in virion assembly, although they were stably expressed and secreted as components of subviral 20-nm hepatitis B surface antigen particles. This suggests that a short C-terminal region of pre-S1 is important for virion formation. Like the wild-type L protein, the mutants of the first class were not glycosylated in their pre-S2 domains; however, this site was used for glycosylation in mutants of the second class, similar to that in the M protein. These findings can be related to a model for the function of the L protein in virion maturation.

Saccharomyces cerevisiae can release hepatitis B virus surface antigen (HBsAg) particles into the medium by its secretory apparatus

We constructed a plasmid that directs the synthesis and secretion of hepatitis B virus (HBV) surface antigen (HBsAg) particles by Saccharomyces cerevisiae. This plasmid contains a proteinase-resistant HBsAg M (M-P31c) gene fused at its 5'-terminus with a chicken-lysozyme signal peptide (C-SIG) gene, which is placed under the yeast GLD (glyceraldehyde-3-phosphate dehydrogenase gene) promoter. The products encoded by the "C-SIG+M-P31c" (LM-P31c) gene were synthesized and assembled themselves into HBsAg particles in yeast cells, and the particles were released into the medium along with poly-HSA (polymerized human serum albumin) binding activity. The HBsAg particles purified from the medium were very similar in density (1.19 g cm-3), size (19.2 +/- 0.8 nm in diameter) and shape (sphere) to human-plasma-derived HBsAg particles. When several sec (temperature-sensitive secretion-defective) mutants were used as host cells, the release of HBsAg particles into the medium was blocked at 37 degrees C but not at 25 degrees C, indicating that the HBsAg particles are exported through the normal yeast secretion pathway. To our knowledge, this is the first report that yeast cells are capable of secreting particles into the medium.

Role of the large hepatitis B virus envelope protein in infectivity of the hepatitis delta virion

The hepatitis delta virus (HDV) is coated with large (L), middle (M), and small (S) envelope proteins encoded by coinfecting hepatitis B virus (HBV). To study the role of the HBV envelope proteins in the assembly and infectivity of HDV, we produced three types of recombinant particles in Huh7 cells by transfection with HBV DNA and HDV cDNA: (i) particles with an envelope containing the S HBV envelope protein only, (ii) particles with an envelope containing S and M proteins, and (iii) particles with an envelope containing S, M, and L proteins. Although the resulting S-, SM-, and SML-HDV particles contained both hepatitis delta antigen and HDV RNA, only particles coated with all three envelope proteins (SML) showed evidence of infectivity in an in vitro culture system susceptible to HDV infection. We concluded that the L HBV envelope protein, and more specifically the pre-S1 domain, is important for infectivity of HDV particles and that the M protein, which has been reported to bear a site for binding to polymerized albumin in the pre-S2 domain, is not sufficient for infectivity. Our data also show that the helper HBV is not required for initiation of HDV infection. The mechanism by which the L protein may affect HDV infectivity is discussed herein.

Deletions in the hepatitis B virus small envelope protein: effect on assembly and secretion of surface antigen particles

The small envelope S protein of hepatitis B virus carrying the surface antigen has the unique property of mobilizing cellular lipids into empty envelope particles which are secreted from mammalian cells. We studied the biogenesis of such particles using site-directed mutagenesis. In this study, we describe the effect of deletions in the N-terminal hydrophobic and hydrophilic domains of the S protein. Whereas short overlapping deletions of hydrophilic sequences flanking the first hydrophobic domain were tolerated, larger deletions of the same sequences were not. Conversely, the hydrophilic region preceding the second hydrophobic domain was not permissive for even short deletions. Deletion of part or all of the first hydrophobic domain also completely blocked secretion, confirming that the entire apolar region serves an essential function. Most of the secretion-defective deletion mutants still entered the secretory pathway and translocated at least the second hydrophilic domain across the membrane of the endoplasmic reticulum. These mutants appeared to remain arrested in a membrane-associated configuration in the endoplasmic reticulum or the cis-Golgi compartment but preserved their capacity for oligomerization with the wild-type S protein. While secretion of wild-type S protein was specifically blocked by the formation of intracellularly retained mixed envelope aggregates, secretion of an unrelated protein (interleukin 9) was completely unaffected.

Expression of large hepatitis B envelope protein mutants using a new expression vector

Aminoterminal deletion mutants of the gene encoding the large hepatitis B surface protein were expressed in COS cells using a new expression vector. The truncated protein showed the same intracellular retention like the wild type protein. The findings show that the secretion block of the protein is not due to its aminoterminal myristylation.

Hepatitis B virus transactivator MHBst: activation of NF-kappa B, selective inhibition by antioxidants and integral membrane localization

C-terminal truncation of the middle surface antigen from hepatitis B virus (MHBs) gives rise to a novel transactivating protein, called MHBst. In this study we show that MHBst like the HBx protein of HBV, can cause nuclear appearance of NF-kappa B DNA binding activity and induce various kappa B-controlled reporter genes. While an inhibitor of protein kinase C could not block gene induction by MHBst, the antioxidants N-acetyl-L-cysteine (NAC) and pyrrolidine dithiocarbamate (PDTC) could potently suppress transactivation at mM and microM concentrations, respectively. Also, kappa B-dependent gene induction by the transactivator HBx was blocked. The effects were selective because PDTC did not interfere with MHBst and HBx-induced activation of the c-fos promoter/enhancer, nor with the basal activity of several other reporter genes lacking functional NF-kappa B binding motifs. Our data suggest that induction of a prooxidant state is crucial for the activation of NF-kappa B by MHBst and HBx and might be related to the hepatocarcinogenic potential of the viral proteins. MHBst had a subcellular localization unusual for a viral transactivator: it appeared to be an integral membrane protein of the endoplasmic reticulum.

Identification of a prenylation site in delta virus large antigen

During replication, hepatitis delta virus (HDV) switches from production of small to large delta antigen. Both antigen isoforms have an HDV genome binding domain and are packaged into hepatitis B virus (HBV)-derived envelopes but differ at their carboxy termini. The large antigen was shown to contain a terminal CXXX box and undergo prenylation. The large, but not the small, antigen formed secreted particles when expressed singly with HBV surface antigen. Mutation of Cys211 in the CXXX box of the large antigen abolished both prenylation and particle formation, suggesting that this site is important for virion morphogenesis.

Characterization of the hepatitis B virus preS/S region encoded transcriptional transactivator

A transactivating function generated by carboxy-terminal truncation of the HBV envelope proteins has been recently described. To characterize the preS/S protein domains responsible for transactivation, preS1/S2/S and preS2/S 3' deletion mutants under the control of the adenoviral major late promoter were tested for their transactivating potential in cotransfection experiments using the c-myc and c-fos regulatory sequences as targets. Deletion of the carboxyterminal hydrophobic domain of the S protein and the presence of the endoplasmic reticulum insertion signal I (ER signal I) are required for the generation of the preS/S transactivating function. Multiple transcription factors binding sites (i.e., TRE, SRE, and NFkB sites) mediated the truncated preS/S-induced activation of the target regulatory sequences. The transactivation phenomenon is linked, at least in part, to the protein kinase C signaling pathway.

Production of infectious hepatitis delta virus in vitro and neutralization with antibodies directed against hepatitis B virus pre-S antigens

Hepatitis delta virus (HDV) particles were produced in Huh7 human hepatoma cells by transfection with cloned hepatitis B virus (HBV) DNA and HDV cDNA. The particles were characterized by their buoyant density, the presence of encapsidated viral RNA, and their ability to infect primary cultures of chimpanzee hepatocytes. Successful infection was evidenced by the appearance of increasing amounts of intracellular HDV RNA after exposure to particles. Infection was prevented when particles were incubated with antibodies directed against synthetic peptides specific for epitopes of the pre-S1 or pre-S2 domains of the HBV envelope proteins before exposure to hepatocytes. These data demonstrate that HDV particles produced in vitro are infectious and indicate (i) that infectious particles are coated with HBV envelope proteins that contain the pre-S1 and pre-S2 regions, (ii) that epitopes of the pre-S1 and pre-S2 domains of HBV envelope proteins are exposed at the surface of HDV particles, and (iii) that antibodies directed against those epitopes have neutralizing activity against HDV.