Unique region of the minor capsid protein of human parvovirus B19 is exposed on the virion surface

Haematological consequences of parvovirus B19 infection

Parvovirus B19, a member of the Erythrovirus genus, is the only member of the Parvoviridae family known to be pathogenic in humans. Erythroviruses are so named because of their tropism and selective replication in erythroid progenitor cells. Haematological consequences of B19 infection arise due to a direct cytotoxic effect on erythroid progenitors in bone marrow with interruption of erythrocyte production. In addition, the physiology of host haematopoiesis and competence of the immune response each determines clinical manifestations of B19 infection: in individuals with underlying haemolytic disorders, B19 infection causes transient aplastic crisis; in immunocompromised patients, persistent B19 infection may develop that manifests as pure red cell aplasia and chronic anaemia; B19 infection in utero may result in fetal death, hydrops fetalis, or congenital anaemia. Diagnosis is based on examination of bone marrow and B19 virological studies. Treatment of persistent infection with immunoglobulin leads to a prompt resolution of the anaemia.

Immunoreactivity against linear epitopes of parvovirus B19 structural proteins. Immunodominance of the amino-terminal half of the unique region of VP1

Three peptides corresponding to the 2-100 amino acids of VP1 unique sequence (VP1-F1), to the 99-227 amino acids of VP1 unique sequence (VP1-F2) and to the 237-781 amino acids of VP1 protein common to VP2 (VP1-F3 = VP2) were produced by prokaryotic expression. The three peptides, which span the entire VP1 structural protein of parvovirus B19 and also the entire VP2 protein, were used to evaluate the immunoreactivity against linear epitopes of these fragments in a large number of serum samples taken in different clinical situations with regards to B19 infection and in some commercial preparations of aspecific immunoglobulins. The data demonstrated that the specific VP1-F1 fragment, corresponding to the amino-terminal half of the VP1 unique region, is immunodominant and can elicit a long lasting immune response in comparison with VP1-F2 and VP1-F3 = VP2. Data regarding the presence of specific IgG to the three fragments in commercial preparations of immunoglobulins demonstrated that the dominant immune response was also against VP1-F1 linear epitopes while IgG against VP1-F2 and IgG against VP1-F3 = VP2 could be found only in high concentrations of Ig preparations. The reported data can be useful as a basis for the development of a B19 recombinant vaccine.

Novel human erythrovirus associated with transient aplastic anemia

Erythrovirus (formerly parvovirus) B19 causes a wide range of diseases in humans, including anemia due to aplastic crisis. Diagnosis of B19 infection relies on serology and the detection of viral DNA by PCR. These techniques are usually thought to detect all erythrovirus field isolates, since the B19 genome is known to undergo few genetic variations. We have detected an erythrovirus (V9) markedly different from B19 in the serum and bone marrow of a child with transient aplastic anemia. The B19 PCR assay yielded a product that hybridized only very weakly to the B19-specific probe and whose sequence diverged more from those of 24 B19 viruses (11 to 14%) than the divergence found within the B19 group (</=6.65%). Restriction enzyme analysis of the V9 genome revealed that this genetic divergence extended beyond the amplified region. Interestingly, serological tests failed to demonstrate a response characteristic of acute B19 infection. V9 could be a new erythrovirus, and new diagnostic tests are needed for its detection.

Epitope mapping of Aleutian mink disease parvovirus virion protein VP1 and 2

Six overlapping fragments of the Aleutian Mink Disease parvoVirus (AMDV) virion protein VP1 and 2 (VP1/2) gene were inserted into the expression vector pMAL-c2. Four of the clones carried large overlapping fragments covering the entire VP1/2 gene. The remaining two clones covered specifically chosen regions within the VP1/2 gene. Using a Western blotting detection system, sera from AMDV-infected mink were tested against the recombinant polypeptides. These studies showed reactions primarily directed against the two AMDV polypeptides ranging from amino acids 297 to 518. Weaker reactions against other regions of the VP1/2 were also observed. The small fusion protein designed to cover the presumed AMDV VP1/2 loop 4 was purified by affinity chromatography and used to develop solid-phase immunoassays. Twelve small synthetic peptides were constructed and used as inhibitors. A peptide covering amino acids S428 to T448 was shown to block the reactivity of a pool of positive mink sera, indicating the presence of one dominant linear epitope.

Rheumatic manifestations of parvovirus B19 infection

Human parvovirus B19 is an emerging DNA virus. B19 infection is common and widespread. Major manifestations of B19 infection are transient aplastic crisis, erythema infectiosum, hydrops fetalis, acute and chronic rheumatoid-like arthropathy, and, in the immunocompromised host, chronic or recurrent bone marrow suppression. A number of less common manifestations of B19 infection include various rash illnesses, neuropathies, and acute fulminant liver failure. Of rheumatologic interest, B19 infection must be differentiated from early presentation of more classic erosive rheumatoid arthritis and, in some cases, systemic lupus erythematosus. It is unlikely that B19 plays a role in classic erosive rheumatoid arthritis, but understanding pathogenesis of B19 arthropathy may provide insights into the mechanisms by which rheumatoid arthritis develops. Evidence for persistence of B19 infection suggests that human parvovirus B19 infection may serve as a model for the study of virus-host interactions and the role of viruses in the pathogenesis of rheumatic diseases.

Watching one's P's and Q's: promiscuity, plasticity, and quasiequivalence in a T = 1 virus

Although quasiequivalence is not needed to explain the assembly of the T = 1 canine parvovirus capsid, the interactions of the 60-fold symmetrical capsid protein with less symmetrical viral components illustrate the elements of plasticity and promiscuity of interactions that are embodied in quasiequivalence. The current analysis is based on interactions of fivefold related proteins with a single peptide running along the fivefold axis, and on interactions of the capsid protein with various fragments of the genomic DNA, each having a different sequence and exposing the protein to interactions with different types of nucleotide base.

Expression of Aleutian mink disease parvovirus capsid proteins in defined segments: localization of immunoreactive sites and neutralizing epitopes to specific regions

The capsid proteins of the ADV-G isolate of Aleutian mink disease parvovirus (ADV) were expressed in 10 nonoverlapping segments as fusions with maltose-binding protein in pMAL-C2 (pVP1, pVP2a through pVP2i). The constructs were designed to capture the VP1 unique sequence and the portions analogous to the four variable surface loops of canine parvovirus (CPV) in individual fragments (pVP2b, pVP2d, pVP2e, and pVP2g, respectively). The panel of fusion proteins was immunoblotted with sera from mink infected with ADV. Seropositive mink infected with either ADV-TR, ADV-Utah, or ADV-Pullman reacted preferentially against certain segments, regardless of mink genotype or virus inoculum. The most consistently immunoreactive regions were pVP2g, pVP2e, and pVP2f, the segments that encompassed the analogs of CPV surface loops 3 and 4. The VP1 unique region was also consistently immunoreactive. These findings indicated that infected mink recognize linear epitopes that localized to certain regions of the capsid protein sequence. The segment containing the hypervariable region (pVP2d), corresponding to CPV loop 2, was also expressed from ADV-Utah. An anti-ADV-G monoclonal antibody and a rabbit anti-ADV-G capsid antibody reacted exclusively with the ADV-G pVP2d segment but not with the corresponding segment from ADV-Utah. Mink infected with ADV-TR or ADV-Utah also preferentially reacted with the pVP2d sequence characteristic of that virus. These results suggested that the loop 2 region may contain a type-specific linear epitope and that the epitope may also be specifically recognized by infected mink. Heterologous antisera were prepared against the VP1 unique region and the four segments capturing the variable surface loops of CPV. The antisera against the proteins containing loop 3 or loop 4, as well as the anticapsid antibody, neutralized ADV-G infectivity in vitro and bound to capsids in immune electron microscopy. These results suggested that regions of the ADV capsid proteins corresponding to surface loops 3 and 4 of CPV contain linear epitopes that are located on the external surface of the ADV capsid. Furthermore, these linear epitopes contain neutralizing determinants. Computer comparisons with the CPV crystal structure suggest that these sequences may be adjacent to the threefold axis of symmetry of the viral particle.

Antibody response to human parvovirus B19 in patients with primary infection by immunoblot assay with recombinant proteins

Human parvovirus B19 recombinant VP1 and VP2 capsid proteins were produced by a procaryotic pGEX expression plasmid to evaluate the humoral response by immunoblot assay in 14 patients with primary infection. The same concentrations of VP1 and VP2 recombinant proteins were used. This demonstrates that VP1 immunoglobulin M detection and/or VP1 immunoglobulin G seroconversion is a reliable marker of primary infections. Consequently, detection of antibodies to B19 VP1 might be helpful for identifying patients at risk for chronic B19 infection or patients who are susceptible to viral reinfection.

Parvovirus B19 infection

Human parvovirus B19, discovered in 1974, is a single-stranded DNA virus which causes erythema infectiosum, arthralgia, aplastic crisis in patients with red cell defects, chronic anaemia in immunocompromised patients, and fetal hydrops. Seroprevalence in developed countries is 2-10% in children less than 5 years, 40-60% in adults more than 20 years, and 85% or more in those over 70 years. The virus may be transmitted by the respiratory route and by transfusion of infected blood and blood products. After an incubation period of six to eight days, viraemia occurs, during which reticulocyte numbers fall dramatically resulting in a temporary drop in haemoglobin of 1 g/dl in a normal person. Clearance of viraemia is dependent on development of specific antibody to the B19 structural proteins, VP1 and VP2. The red cell receptor for the virus is blood group P antigen. Diagnosis in immunocompetent persons depends on detection of specific IgM in serum. Diagnosis in immunocompromised persons depends on detection of B19 antigen or DNA in serum. There is no specific treatment for B19 infection; however, human normal immunoglobulin may be used as a source of specific antibody in chronically infected persons. A recombinant parvovirus B19 vaccine is under development.

Follow-up study of clinical and immunological findings in patients presenting with acute parvovirus B19 infection

This study was undertaken to examine the natural history of parvovirus B19 infection in persons without a known immune defect in terms of both clinical symptoms and immune responsiveness to the virus. Fifty-three patients with acute B19 infection (positive for serum anti-B19 IgM) were studied; symptoms at acute infection were rash and arthralgia (n = 26), rash (n = 7), arthralgia (n = 16), aplastic crisis (n = 3), and intrauterine fetal death (n = 1). Patients were followed for 26-85 months (mean 57 months) and reassessed for persistent symptoms, anti-B19 antibodies, and antibodies to the unique region of B19 VP1. There were 23 cases of arthralgia persisting for longer than 1 year after acute infection. One of these patients, a 48-year-old woman at follow-up, had had persistent arthralgia for 4 years following acute B19 infection, had rheumatoid factor at a titre of 1920 IU/ml detected at follow-up, and had been independently diagnosed as having rheumatoid arthritis at the time of follow-up. All 53 patients were positive for serum anti-B19 IgG compared to 45 of 53 age- and sex-matched control patients, a significant difference (two-tailed P value = 0.008). All test patients at follow-up and control patients were negative for serum anti-B19 IgM and antibodies to the unique region of B19 VP1. Serum from acute infection from 33 of 53 test patients was tested for antibodies to the unique region of VP1, and 16 of these were positive. The presence of this antibody did not correlate with subsequent duration of symptoms but did correlate with a short interval between symptom onset and blood sampling. The unique region of B19 VP1 is known to be crucial for a successful humoral response to the virus, and it seems that the antigenic role played by this region is important only during the acute phase of B19 infection.

Modest truncation of the major capsid protein abrogates B19 parvovirus capsid formation

In vitro studies have suggested an important role for the minor capsid protein (VP1) unique region and the junction between VP1 and the major capsid protein (VP2) in the neutralizing immune response to B19 parvovirus. We investigated the role of the NH2-terminal region of the major structural protein in capsid structure by expressing progressively more truncated versions of the VP2 gene followed by analysis using immunoblotting and electron microscopy of density gradient-purified particles. Deletion of the first 25 amino acids (aa) of VP2 did not affect capsid assembly. Altered VP2 with truncations to aa 26 to 30, including a single amino acid deletion at position 25, failed to self-assemble but did participate with normal VP2 in the capsid structure. The altered region corresponds to the beginning of the beta A antiparallel strand. Truncations beyond aa 30 were incompatible with either self-assembly or coassembly, probably because of deletion of the beta B strand, which helps to form the core structure of the virus.

Extent of sequence variability in a genomic region coding for capsid proteins of B19 parvovirus

Genomic variability in human parvovirus B19 was analysed by direct partial sequencing of different isolates collected in Italy between 1989 and 1994. DNA was purified from viremic serum samples and the region of viral genome coding for structural proteins was amplified by polymerase chain reaction and partially sequenced (nt. 2400-3400). Data were compared to reference isolates Wi (U.K., 1973) and Au (U.S.A., 1982). The average relative distance between isolates was estimated at the low level of 0.61%, comparable with the distance to reference isolates. Out of 22 nucleotide substitutions found, 9 resulted in amino acid changes. From our results, this region of human parvovirus B19 genome appears to be stably conserved.

B19 parvovirus

B19 parvovirus is pathogenic in man and causes a variety of clinical illnesses, among them several haematological diseases. Acute infection of a host with underlying haemolysis produces transient aplastic crisis; of the midtrimester fetus, hydrops fetalis; and of an immunocompromised patient, pure red cell aplasia. The target of B19 parvovirus infection is the human erythroid progenitor cell. Infection is cytotoxic due to expression of the viral nonstructural protein. The virus can be propagated in cultures of human bone marrow, blood, and fetal liver. Humoral immunity normally terminates infection, and commercially available immunoglobulin can be used to treat persistent infection. Recombinant capsids, produced in a baculovirus system, are suitable as a vaccine reagent.

Peptides derived from the unique region of B19 parvovirus minor capsid protein elicit neutralizing antibodies in rabbits

B19 parvovirus is pathogenic in humans. The virus propagates in the bone marrow, where it is cytotoxic to erythroid progenitor cells. Antibodies appear in blood after infection and neutralize virus in vitro; infection appears to confer lasting immunity. The predominant immune response on immunoblot is to the minor capsid protein (VP1), which differs from the major capsid protein (VP2) by an additional 227 amino acids. We previously demonstrated that antisera directed to a fusion protein containing this unique region or to more limited fusion peptides of 50-100 amino acids each neutralized virus. In the current work, we tested synthetic peptides of about 20 amino acids derived from the VP1 unique region for their ability to elicit a neutralizing antibody response in rabbits. Individual peptides were covalently linked to a lysine core to produce a multivalent antigen. Animals produced antibodies to all 13 synthetic peptides, as determined by ELISA. At 12 weeks, animals injected with one of three peptides--two from the far amino terminus and the third from the center of the unique region--had produced antibodies that completely neutralized virus; by 16 weeks, antisera elicited with another four peptides also were effective. In summary, we identified regions containing neutralizing epitopes within the first 80 amino acids and amino acids 148-205 of the unique region. Our data suggest that synthetic peptides might be useful vaccine reagents for protection against parvovirus infection in humans.

Parvovirus particles as platforms for protein presentation

Empty capsids of the human pathogenic parvovirus B19 can be produced in a baculovirus system. B19 capsids are composed mainly of major capsid protein (VP2) and a small amount of minor capsid protein (VP1); VP1 is identical to VP2 but contains an additional 227-aa N-terminal region ("unique" region). A portion of that region of VP1 is external to the capsid, and VP1 is not required for capsid formation. We substituted the unique region with a sequence encoding the 147 aa of hen egg white lysozyme (HEL) and constructed recombinant baculoviruses with variable amounts of retained VP1 sequence joined to the VP2 backbone. After cotransfection with VP2 baculovirus and expression in insect cells, capsids were purified by density sedimentation. Purified recombinant capsids contained HEL. External presentation of HEL was demonstrated by immunoprecipitation, ELISA, and immune electron microscopy using anti-lysozyme monoclonal antibodies or specific rabbit antisera. Empty particles showed enzymatic activity in a micrococcal cell wall digestion assay. Rabbits inoculated with capsids made antibodies to HEL. Intact heterologous protein can be incorporated in B19 particles and presented on the capsid surface, properties that may be useful in vaccine development, cell targeting, and gene therapy.

Formation of empty B19 parvovirus capsids by the truncated minor capsid protein

We previously reported that empty capsids of B19 parvovirus were formed by the major capsid protein (VP2) alone expressed in a baculovirus system, but the minor capsid protein (VP1), longer by 227 amino acids, alone did not form empty capsids. We report here further investigations of the constraints on capsid formation by truncated versions of VP1. Studies were performed with recombinant baculoviruses expressed in Sf9 cells. Severely shortened VP1, extended beyond the VP2 core sequence by about 70 amino acids of the unique region, formed capsids normal in appearance; longer versions of VP1 also formed capsids but did so progressively less efficiently and produced capsids of more markedly dysmorphic appearance as the VP1-unique region was lengthened.

Subunit interaction in B19 parvovirus empty capsids

B19 parvovirus is a small single-stranded DNA virus with a genome that encodes only two structural proteins, designated VP1 and VP2. 60 copies of the structural proteins assemble into the viral capsid, with approximately 95% VP2 and 5% VP1. Recombinant empty capsids composed of VP2 alone or of VP2 and VP1 self-assemble into particles that are morphologically indistinguishable from full virions. Empty capsids containing both VP2 and VP1 elicit a strong neutralizing antibody response when used to immunize rabbits. Capsids containing only VP2 are similarly antigenic but elicit only weak neutralizing activity. We performed fine structure epitope mapping by measuring the reactivity of antisera raised against capsids composed of VP2 and VP1 or VP2 alone against 85 overlapping peptides spanning the sequence of the two structural proteins. A profile of the antigenic difference between empty capsids with and without VP1 was produced from the resulting data. This profile divided the sequence of the structural proteins into four regions that correlated well with expected viral structures. Thus, the addition of a small number of VP1 residues altered the antigenicity of the entire capsid. The major area of enhanced antigenicity is homologous to the spike of canine parvovirus, an area known to contain both neutralizing and host-range determinants. Our data are consistent with a model in which the unique region of VP1 is necessary for the virus to assume its mature capsid conformation.

Hepatitis C virus NS3 protein polynucleotide-stimulated nucleoside triphosphatase and comparison with the related pestivirus and flavivirus enzymes

Sequence motifs within the nonstructural protein NS3 of members of the Flaviviridae family suggest that this protein possesses nucleoside triphosphatase (NTPase) and RNA helicase activity. The RNA-stimulated NTPase activity of this protein from prototypic members of the Pestivirus and Flavivirus genera has recently been established and enzymologically characterized. Here, we experimentally demonstrate that the NS3 protein from a member of the third genus of Flaviviridae, human hepatitis C virus (HCV), also possesses a polynucleotide-stimulated NTPase activity. Characterization of the purified HCV NTPase activity showed that it exhibited reaction condition optima with respect to pH, MgCl2, and salt identical to those of the representative pestivirus and flavivirus enzymes. However, each NTPase also possessed several unique properties when compared with one another. Notably, the profile of polynucleotide stimulation of the NTPase activity was distinct for the three enzymes. The HCV NTPase was the only one whose activity was significantly enhanced by a deoxyribopolynucleotide. Additional distinguishing features among the three enzymes relating to the kinetic properties of their NTPase activities are discussed. These studies provide a foundation for investigation of the putative RNA helicase activity of these proteins and for further study of the role of the NS3 proteins of members of the Flaviviridae in the replication cycle of these viruses.

Neutralizing linear epitopes of B19 parvovirus cluster in the VP1 unique and VP1-VP2 junction regions

Presentation of linear epitopes of the B19 parvovirus capsid proteins as peptides might be a useful vaccine strategy. We produced overlapping fusion proteins to span the viral capsid sequence, inoculated rabbits, and determined whether the resulting antisera contained antibodies that neutralized the ability of the virus to infect human erythroid progenitor cells. Antibodies that bound to virus in an enzyme-linked immunosorbent assay were present in antisera raised against 10 of 11 peptides; strongest activity was found for antisera against the carboxyl-terminal half of the major capsid protein. However, strong neutralizing activity was elicited in animals immunized with peptides from the amino-terminal portion of the unique region of the minor capsid protein and peptides containing the sequence of the junction region between the minor and major capsid proteins. The development of neutralizing activity in animals was elicited most rapidly with the fusion peptide from the first quarter of the unique region. A 20-amino-acid region of the unique region of the minor capsid protein was shown to contain a neutralizing epitope. Multiple antigenic peptides, based on the sequence of the unique region and produced by covalent linkage through a polylysine backbone, elicited strong neutralizing antibody responses. Synthetic peptides and fusion proteins containing small regions of the unique portion of the minor capsid protein might be useful as immunogens in a human vaccine against B19 parvovirus.

RNA-stimulated NTPase activity associated with yellow fever virus NS3 protein expressed in bacteria

The nonstructural protein NS3 of the prototypic flavivirus, yellow fever virus, was investigated for possession of an NTPase activity. The entire NS3 protein coding sequence and an amino-terminal truncated version thereof were engineered into Escherichia coli expression plasmids. Bacteria harboring these plasmids produced the expected polypeptides, which upon cell disruption were found in an insoluble aggregated material considerably enriched for the NS3-related polypeptides. Solubilization and renaturation of these materials, followed by examination of their ability to hydrolyze ATP, revealed an ATPase activity present in both the full-length and amino-terminal truncated NS3 preparations but not in a similarly prepared fraction from E. coli cells engineered to express an unrelated polypeptide. The amino-terminal truncated NS3 polypeptide was further enriched to greater than 95% purity by ion-exchange and affinity chromatography. Throughout the purification scheme, the ATPase activity cochromatographed with the recombinant NS3 polypeptide. The enzymatic activity of the purified material was shown to be a general NTPase and was dramatically stimulated by the presence of particular single-stranded polyribonucleotides. These results are discussed in view of similar activities identified for proteins of other positive-strand RNA viruses.