Localization of a sequential B-epitope in the VP2 protein of hepatitis A virus.

A set of synthetic peptides derived from the capsid protein of hepatitis A virus was used to search for B-epitopes. Peptides from the 115-139 region of the VP1 protein, from the 69-99 region of the VP2 protein and peptide 137-150 from the VP3 protein were found to react with monoclonal and polyclonal anti-HAV antibodies. MAPs based on 64-80 and 66-80 fragments of VP3 were reactive as well. Peptides, their conjugates with protein carriers and MAPs were used for antipeptide antibody production. Only free peptide 69-99 from the VP2 protein caused formation of HAV binding antibodies.

Complete nucleotide sequence of a cytopathic hepatitis A virus strain isolated in Italy.

The molecular basis of the cytopathic effect induced in cell culture by some hepatitis A virus (HAV) strains and variants has not been determined. In order to assess the molecular mechanism(s) underlying this particular phenotype the genome of an Italian cytopathic isolate (strain FG) was sequenced from cDNAs obtained by RT-PCR. Sequence analysis revealed the presence of mutations common to either adapted or cytopathic variants of HAV. In particular, amino acid deletions in proteins VP1 and 3A were detected. Expression of protein 3A in E. coli showed that the N-terminal deletion renders this protein toxic to bacteria.

Conformational changes in the hepatitis A virus capsid in response to acidic conditions.

Low pH values encountered during uptake of viruses by receptor-mediated endocytosis have been shown to expose hydrophobic residues of many viruses and result in viral conformational changes leading to uncoating of the viral genome. An assay for hydrophobicity utilising the non-ionic detergent Triton X-114 was established, making use of metabolically-labelled hepatitis A virus (HAV). In this assay, hydrophilic proteins interact with the aqueous (buffer) phase, while hydrophobic proteins interact with the Triton (detergent) phase. HAV particles interact with the aqueous phase at neutral pH, whereas, under acidic conditions, HAV was found predominantly in the detergent phase. This indicates that the capsid of HAV undergoes conformational changes rendering the particle more hydrophobic under acidic conditions. A further two conformational changes were found in HAV on exposure to low pH, as detected by changes in buoyant density in CsCl gradients. These were maturation of provirions to virions and the formation of dense particles. These results may have implications for uncoating of the HAV RNA genome, and these conformational changes could represent intermediates in the viral uncoating process.

Identification of genetic variants of hepatitis A virus.

Although detection of hepatitis A virus (HAV) has been greatly aided by the development of polymerase chain reaction (PCR) technology, identification of genetic variants requires sequencing PCR products, which necessarily limits the length of the HAV genome (typically 2%) that can be analyzed. From a regulatory standpoint, identification of the specific strain detected by PCR is a prerequisite not only to overrule contamination of test samples in the diagnostic laboratory, but also to possibly locate the origin of the virus detected by PCR. We explored alternatives to sequencing PCR products to achieve these goals. The findings indicate that restriction fragment length polymorphism (RFLP) analysis of PCR products from two noncontiguous regions of the HAV genome encompassing 765 nucleotides (approximately 10% of the genome) by the restriction endonucleases HinfI and AluI, which cut frequently within the HAV genome, can distinguish the common tissue culture adapted strains of HAV from stool isolates. The resolution can be greatly enhanced by combining single strand conformation polymorphism (SSCP) analysis with restriction enzyme digestion, when most of the seventeen strains analyzed could be identified.

[Purification and proteic characterization of a Cuban strain of the hepatitis A virus]. / Purificación y caracterización proteica de una cepa cubana del virus de la hepatitis A.

The purification and protein characterization of one of the Cuban isolated strains of hepatitis A virus was carried out. For this, it was necessary to separate the virus from the infected cell by extraction steps with detergents, concentration by ultrafiltration and finally, ultracentrifugation in saccharosoglycerol discontinuous gradient. Protein concentration, as well as the antigenic activity in the different fractions of the gradient were determined. For the protein characterization of the microorganism, those fractions with the greatest specific activity were analyzed by polyacrylamide gel electrophoresis and by Western blotting. It was shown that the viral material was purified and concentrated in the last fractions of the gradient. Bands corresponding to the structural proteins of hepatitis A were observed through electrophoresis and Western blotting.

Synthesis, lipophilic derivatization and interaction with liposomes of HAV-VP3 (102-121) sequence by using spectroscopic techniques.

Hepatitis A virus (HAV) is composed mainly of three structural capsid proteins: VP1, VP2 and VP3. Our group has reported the synthesis and the immunogenic evaluation of VP3 (110-121) peptide sequence. In the present work, in order to stimulate a T-cell immune response, we have selected the HAV-VP3 (102-121) peptide which has maximum amphipathicity. Its synthesis was carried out manually in the solid phase and semipreparative HPLC was used for purification of the crude peptide. Finally the purified peptide was characterized by analytical HPLC, amino acid analysis and MS. A palmitoyl derivative of VP3 (102-121) was synthesized to modify the hydrophobicity of the peptide. Both free and lipophilically derivatized peptides were incorporated into multilamelar liposomes. Physicochemical studies of the HAV-related peptides described above were carried out using monolayers as membrane models. Compression isotherms, surface activity and penetration kinetics into dipalmitoylphosphatidylcholine monolayers were determined. Moreover, changes in the fluidity of bilayers induced by these peptides were determined by means of polarizable probes such as 8-anilino-1-naphthalenesulfonic acid and 1,6-diphenyl-1,3,5-hexatriene. The integrity of the membranes has also been ascertained with the carboxyfluorescein.

Interaction study of peptide from VP3 capsid protein of hepatitis A virus through monolayers and fluorescence spectroscopy.

A synthetic peptide with the sequence [Lys113]VP3(110--121): FWRKDLVFDFQV, corresponding to an epitope of the VP3 capsid protein of hepatitis A virus (HAV), was synthesized by solid phase and characterized. To obtain insight into its physicochemical properties and to understand its possible mechanism of action at the membrane level, interaction with DPPC or DPPC/DPPG (95/5) liposomes and lipid monolayers of DPPC, DPPG, SA, PS, PA and SM were studied by fluorescence spectroscopy and Langmuir--Blotgett films technique, respectively. Fluorescence studies showed that the peptide was in a hydrophobic environment when DPPC liposomes were used. The addition of a 5% of a charged lipid, DPPG, to the preparations changed the preference of the peptide towards a polar surrounding. However, the peptide had a high surface activity (nmol/L) and was able to incorporate into lipid monolayers. Interaction was higher with charged phospholipids than with neutral ones. These results may have physiological significance in the mechanism of infection of host hepatic cells by HAV.

Properties and classification of hepatitis A virus.

Hepatitis A virus (HAV) is a member of the picornavirus family. It was first provisionally classified as enterovirus 72, but subsequent determinations of its nucleotide and amino acid sequences showed them to be sufficiently distinct to assign the virus to a new genus. Heparna-virus (Hep-A-RNA-virus) has been suggested as the genus name. HAV shares the key properties of the picornavirus family: an icosahedral particle 28 nm in diameter with cubic symmetry, composed of 30% RNA and 70% protein. The genome is single-stranded 7.48 kb RNA, linear and positive-sense. Like other picornaviruses, HAV possesses four major polypeptides cleaved from a large precursor polyprotein. The surface proteins VP1 and VP3 are major antibody-binding sites. The internal protein VP4 is much smaller than the VP4s of other picornaviruses. As other picornaviruses, HAV has no envelope and replicates in the cytoplasm. HAV is stable to treatment with either and acid, and is much more heat-resistant than other picornaviruses. It withstands 60 degrees C for 1 h. MgCl2 stabilizes the virus to withstand temperatures up to 80 degrees C. The relative resistance of HAV to disinfection indicates a need for extra precautions in dealing with hepatitis patients and their products. Only one serotype is known. There is no antigenic cross-reactivity with other hepatitis viruses. HAV initially was identified in stool and liver preparations by employing immune electron microscopy as the detection system. Chimpanzees and marmoset monkeys are susceptible to HAV. HAV has been cultivated serially in primary explant cultures of adult marmoset livers and in cell lines of primate origin.(ABSTRACT TRUNCATED AT 250 WORDS)

Replication of hepatitis A virus and processing of proteins.

Isolation and propagation of hepatitis A virus (HAV) in cell culture is routinely possible. All primary HAV isolates and most established virus strains, however, show a protracted replication behaviour and tend to establish a persistent infection. Rapidly replicating, cytolytic variant viruses can be selected from persistently infected cultures under distinct conditions. Factors critical for the outcome of HAV infection include the genetics of the virus, the physiological state of the infected cell, the presence of defective interfering particles, synthesis and encapsidation of viral RNA and possibly synthesis and processing of viral proteins. Analysis of the latter events have proved to be difficult. Only seven of the 11 peptides coded for by the HAV genome have been experimentally identified and the sequence of cleavages by which they are released from the precursor polyprotein is still a matter of discussion.

In situ hybridization in viral hepatitis.

In situ hybridization (ISH) is a sensitive and specific technique for detecting nucleic acids in intact cells. Visualization of the target sequences by autoradiography or immunohistochemistry allows their precise subcellular localization and quantitation. The application of ISH techniques has contributed to the understanding of the complex replicative cycle of hepatitis B virus. More recently, hepatitis delta and C virus replication has also been studied by this technique. ISH-based assays have finally been used to follow the replication of cytomegalovirus within the transplanted liver. Although ISH is a powerful tool for the molecular biologist, its clinical significance in the diagnosis and prognosis of human hepatitis virus infections has yet to be fully evaluated.

Hepatitis A virus proteins.

The RNA genome of hepatitis A virus (HAV) shares common characteristics of the picornavirus family. However, the nucleotide or amino acid sequences are distantly related with other members of the family. Like other picornaviruses, HAV proteins are cleaved from a large polyprotein (PO), but the processing and some products are quite different. The 3C protein is the sole processing enzyme, and the primary cleavage takes place at the 2A/2B site. Several VP1-2A sites are proposed. In some strains, the intermediate VP1-2A polypeptides are assembled in the virion. The VP4 is very small and not detected in the mature virion. Some mutations in 2B, 2C and 3A proteins are identified to enhance viral replication or to induce cytopathogenic effects in the viruses adapted to cell cultures.

Anti-hepatitis A virus antibody response elicited in mice by different forms of a synthetic VP1 peptide.

Peptide VP1 (11-25) of the capsid of hepatitis A virus was synthesized by the Fmoc-polyamide solid phase method, and administered to mice in different forms: (1) free, (2) encapsulated in multilamellar liposomes, (3) coupled to keyhole limpet hemocyanin (KHL), and (4) incorporated into a tetrameric branched lysine core. The highest anti-VP1 peptide responses were generated by synthetic peptides entrapped into liposomes and coupled to KLH. No anti-HAV response was generated with the free peptide, while all the other forms induced both anti-HAV and HAV-neutralizing antibodies. Maximum neutralization indices were observed in ascites from mice treated with liposome-entrapped and KLH peptides.

Acute auto immune haemolytic anaemia secondary to hepatitis A infection.

Auto immune haemolytic anaemia has been described in association with a variety of hepatotropic viruses, in particular cytomegalovirus, Epstein-Barr virus and hepatitis B. There is a well-recognized association between chronic active hepatitis and auto immune haemolytic anaemia. We present the first reported case of acute hepatitis A which resulted in a fall in haemoglobin concentration from 14.6 to 4.5 g/dl due to an acute haemolytic anaemia with an associated rise in bilirubin from 149 to 960 mumol/l.

Hepatitis A virus replication: an intermediate in the uncoating process.

Dense, RNase-sensitive, VP2-containing, non-infectious hepatitis A virus (HAV) particles were found to be formed at early times after the infection of cultured cells. These particles formed with kinetics mirroring those reported for HAV uncoating. The kinetics of the formation of dense HAV particles corresponded to a decrease in detectable, mature input virions, as detected by RNA dot blot hybridization of CsCl density gradient fractions. The dense HAV particles did not appear to have altered sedimentation coefficients, and as the fate of small capsid protein VP4 is not yet known, these particles cannot yet be termed 'A particles' or 'infectosomes', as have the uncoating intermediates in some picornavirus-cell systems.

Fluorescence study on the interaction of a multiple antigenic peptide from hepatitis A virus with lipid vesicles.

The interaction of the multiple antigenic peptide MAP4VP3 with lipid membranes has been studied by spectroscopic techniques. MAP4VP3 is a multimeric peptide that corresponds to four units of the sequence 110-121 of the capsid protein VP3 of hepatitis A virus. In order to evaluate the electrostatic and hydrophobic components on the lipid-peptide interaction, small unilamelar vesicles of different compositions, including zwitterionic dipalmitoylphosphatidylcholine (DPPC), anionic dipalmitoylphosphatidylcholine/phatidylinositol (DPPC:PI 9:1), and cationic dipalmitoylphosphatidylcholine/stearylamine (DPPC:SA 9.5:0.5), were used as membrane models. Intrinsic tryptophan fluorescence changes and energy transfer experiments show that MAP4VP3 binds to all three types of vesicles with the same stoichiometry, indicating that the electrostatic component of the interaction is not important for binding of this anionic peptide. Steady-state polarization experiments with vesicles labeled with 1,6-diphenyl-1,3,5-hexatriene or with 1-anilino-8-naphtalene sulphonic acid indicate that MAP4VP3 induces a change in the packing of the bilayers, with a decrease in the fluidity of the lipids and an increase in the temperature of phase transition in all the vesicles. The percentage of lipid exposed to the bulk aqueous phase is around 60% in intact vesicles, and it does not change upon binding of MAP4VP3 to DPPC vesicles, indicating that the peptide does not alter the permeability of the membrane. An increase in the amount of lipid exposed to the aqueous phase in cationic vesicles indicates either lipid flip-flop or disruption of the vesicles. Binding to DPPC vesicles occurs without leakage of entrapped carboxyfluorescein, even at high mol fractions of peptide. However, a time-dependent leakage is seen with cationic DPPC/SA and anionic DPPC/PI vesicles, indicating that the peptide induces membrane destabilization and not lipid flip-flop. Resonance energy transfer experiments show that MAP4VP3 leakage from cationic vesicles is due to membrane fusion, whereas leakage from anionic vesicles is not accompanied by lipid mixing. Results show that MAP4VP3 interacts strongly with the lipid components of the membrane, and although binding is not of electrostatic nature, the bound form of the peptide has different activity depending on the membrane net charge; thus, it is membrane disruptive in cationic and anionic vesicles, whereas no destabilizing effect is seen in DPPC vesicles.

Membrane fusion induced by a lipopeptidic epitope from VP3 capside protein of hepatitis A virus.

Palmitoyl-VP3(110--121) (PVP3) is a synthetic lipopeptide derivative of a continuous epitope from the VP3 capsid protein of hepatitis A virus, and it is highly immunogenic in vivo. We have investigated the interaction of PVP3 with lipid model membranes of varying surface charge. Binding of PVP3 to anionic vesicles of PC/SM/PE/PS; (PC) 1-palmitoyl-2-oleoyl-phosphatidylcholine, (SM) sphingomyelin, (PE) 1,2-dipalmitoyl-phosphatidylethanolamine and (PS) L-alpha-phosphatidyl-L-serine, a composition that mimics the lipid component of natural membranes, was determined by tryptophan fluorescence and quenching experiments. In addition, and given the anionic net charge of the lipopeptide, binding to zwitterionic (PC/SM/PE) and cationic PC/SM/PE/DOTAP (DOTAP) 1,2-dioleoyl-3-trimethylammonium-propane mixtures was also determined. PVP3 binds to all three types of vesicles, but it adopts different forms depending on the electrical charge of the interface. This conclusion is supported by the insertion of PVP3 into lipid monolayers of the same charges spread at the air-water interface. The bound lipopeptide has membrane-destabilizing effects in all three vesicle compositions, as demonstrated by leakage of vesicle contents, whereas lipid mixing only occurs in cationic liposomes. Our results provide useful information for the design of a liposomal system that promotes a direct delivery of the membrane-incorporated immunogen to the immunocompetent cells, potentially increasing the immune response from the host.

Conformational behavior of the HAV-VP3(110-121) peptidic sequence and synthetic analogs in membrane environments studied by CD and computational methods.

The present study was undertaken to examine the structural features that may be important to explain the immunogenicity of the (110-121) peptide sequence (FWRGDLVFDFQV) of VP3 capsid protein of hepatitis A virus. A conformational analysis of the preferred conformations by CD and molecular mechanics was carried out. Present results suggest that the interaction with liposomes as biomembrane model induces and stabilizes the amphipathic beta-structure of the peptide. To study the contribution of amino acid replacements at the RGD tripeptide as well as the influence of the peptide chain length on peptide conformation, solid-phase peptide synthesis of several peptide analogs was carried out and the peptide conformation was studied using CD spectroscopy. The results show that the RGD sequence is necessary to induce the beta-structure in the presence of liposomes.

Identification of hepatitis A virus non-structural protein 2B and its release by the major virus protease 3C.

The RNA genome of hepatitis A virus (HAV) encodes a giant polyprotein that is putatively cleaved proteolytically into four structural and seven non-structural proteins. So far, most of the proposed non-structural proteins and their respective cleavage sites have not been identified. A vaccinia virus recombinant (vRGORF) containing the complete HAV ORF under the control of the bacteriophage T7 promoter was used to express HAV in recombinant animal cells (BT7-H) that constitutively expressed T7 DNA-dependent RNA polymerase. A HAV-specific 27.5 kDa expression product was identified as peptide 2B. The 27.5 kDa 2B antigen was also found in HAV-infected MRC-5 cells. The N-terminal amino acid residues of the new peptide 2B are Ala-Lys-Ile-Ser-Leu-Phe and polyprotein cleavage between 2A and 2B occurred at amino acids 836-837 (Gln-Ala). Furthermore, heterologous expression in the same system of regions P1-P2 and of the protease 3C (3Cpro) gene, showed that P1-P2 polyprotein is not cleaved autocatalytically but by 3Cpro. Hence, 3Cpro is effective in cleaving the polyprotein 2A-2B junction.

Differences in secondary structure of HAV-synthetic peptides induced by the sequential order of T- and B-cell epitopes.

The present study was undertaken to examine the structural features of two peptide constructs designed on the basis of linear combination of B and T-cell epitopes in different orientations (BT and TB) that may be important to explain the differences in the elicited antihepatitis A virus immune response and in the interaction with biological model membranes. A CD study was carried out and the corresponding quantitative analysis of the experimental data was done using deconvolution computer programs. Moreover, fluorescence experiments were performed to analyze differences in the fluorescence emission spectra of both molecules. The main conformational difference by CD studies was obtained working in aqueous medium. Although the TB sequence adopted a preferably random coil structure, the BT peptide was best fitted with beta-type structures. These results are further supported by fluorescence studies. These findings have relevance for the design of synthetic immunopeptides.

Genetic analysis of hepatitis A virus outbreak in France confirms the co-circulation of subgenotypes Ia, Ib and reveals a new genetic lineage.

Genetic analysis of selected genome regions of hepatitis A Virus (HAV) suggested that distinct genotype could be defined in different geographic locations. In order to study the degree of genetic variability among HAV isolated during a single epidemic outbreak, sequences from a 148 base pair segment within the VP1 amino terminal region were obtained for eight distinct HAV isolates from an outbreak that occurred in North Bretagne (France). These sequences were compared among themselves and with published sequences from 30 different strains that represented different HAV sub-genotypes that were isolated all over the world. Phylogenetic analysis revealed an extensive genetic heterogeneity among strains belonging to the same outbreak and revealed co-circulation of sub-genotype IA, IB, and the presence of IIIA sub-genotype for the first time in a Mediterranean country.