Determination of the protective epitopes on the glycoproteins of Venezuelan equine encephalomyelitis virus by passive transfer of monoclonal antibodies

We have previously characterized seven unique antigenic epitopes on the two envelope glycoproteins of the Venezuelan equine encephalomyelitis (VEE) virus vaccine strain, TC-83, by using monoclonal antibodies. The in vitro function of virus neutralization was primarily associated with one epitope on the gp56 (gp56c). To determine which epitopes were important in protecting animals from VEE infection, purified monoclonal antibodies were inoculated i.v. into 3-wk-old Swiss mice. Twenty-four hours later these animals were challenged i.p. with 100 IPLD50 of virulent VEE virus (Trinidad donkey). High-avidity anti-gp56c, anti-gp50b, anti-gp50c, and anti-gp50d monoclonal antibodies protected animals from virus challenge. Rabbit antisera to the gp56 and the gp50 glycoproteins were also effective in protecting mice from challenge with virulent VEE virus. Less antibody was needed to protect animals if the antibody was directed against the critical neutralization site. Less avid antibodies to the gp56c and gp50b epitopes demonstrated little or no protection in vivo. Protection, therefore, appeared to be a function of the passive antibody's specificity, avidity, and ability to bind to virion antigenic determinants topologically proximal to the critical neutralization site.     

Study of the antigenic structure of the E1 glycoprotein of the Venezuelan equine encephalomyelitis virus using monoclonal antibodies]

The collection of eight rat and mouse hybridomas secreting the high affinity monoclonal antibodies to glycoprotein E1 of the Venezuelan equine encephalomyelitis has been obtained. The antigenic structure of E1 protein has been studied with the use of these antibodies for the strains Trinidad, TC-83 and 230 of the virus. Antigenic map of glycoprotein E1 based on competition radioimmunoanalysis is proposed. Five sites are mapped including eight epitopes binding monoclonal antibodies. Antibodies to sites E1-1, E1-3 and E1-5 are crossreactive in interaction with the virus of Venezuelan equine encephalomyelitis, while antibodies to site E1-5 interact also with the virus of tick-borne encephalitis. Antibodies to site E1-1 possess the protective effect and lack the neutralizing effect in tissue cultures. Antibodies to all sites of E1 protein are devoid of ability to neutralize the Venezuelan equine encephalitis virus.     

Use of a lambda gt11 expression library to localize a neutralizing antibody-binding site in glycoprotein E2 of Sindbis virus.

The Sindbis virus envelope contains two species of integral membrane glycoproteins, E1 and E2. These proteins form heterodimers, and three dimeric units assemble to form spikes incorporated into the viral surface which play an important role in the specific attachment of Sindbis virus to host cells. To map the neutralization epitopes on the surface of the virus, we constructed a lambda gt11 expression library with cDNA inserts 100 to 300 nucleotides long obtained from randomly primed synthesis on Sindbis virus genomic RNA. This library was screened with five different neutralizing monoclonal antibodies (MAbs) specific for E2 (MAbs 50, 51, 49, 18, and 23) and with one neutralizing MAb specific for E1 (MAb 33). When 10(6) lambda gt11 plaques were screened with each antibody, four positive clones that reacted with E2-specific MAb 23 were found. These four clones contained overlapping inserts from glycoprotein E2; the domain from residues 173 to 220 of glycoprotein E2 was present in all inserts, and we concluded that this region contains the neutralization epitope recognized by the antibody. No clones that reacted with the other antibodies examined were found, and we concluded that these antibodies probably recognize conformational epitopes not present in the lambda gt11 library. We suggest that the E2 domain from residues 173 to 220 is a major antigenic determinant of Sindbis virus and that this domain is important for virus attachment to cells.     

Identification of antigenically important domains in the glycoproteins of Sindbis virus by analysis of antibody escape variants.

To study important epitopes on glycoprotein E2 of Sindbis virus, eight variants selected to be singly or multiply resistant to six neutralizing monoclonal antibodies reactive against E2, as well as four revertants which had regained sensitivity to neutralization, were sequenced throughout the E2 region. To study antigenic determinants in glycoprotein E1, four variants selected for resistance to a neutralizing monoclonal antibody reactive with E1 were sequenced throughout the E2 and E1 regions. All of the salient changes in E2 occurred within a relatively small region between amino acids 181 and 216, a domain that encompasses a glycosylation site at residue 196 and that is rich in charged amino acids. Almost all variants had a change in charge, suggesting that the charged nature of this domain is important for interaction with antibodies. Variants independently isolated for resistance to the same antibody were usually altered in the same amino acid, and reversion to sensitivity occurred at the sites of the original mutations, but did not always restore the parental amino acid. The characteristics of this region suggest that this domain is found on the surface of E2 and constitutes a prominent antigenic domain that interacts directly with neutralizing antibodies. Previous studies have shown that this domain is also important for penetration of cells and for virulence of the virus. Resistance to the single E1-specific neutralizing monoclonal antibody resulted from changes of Gly-132 of E1 to either Arg or Glu. Analogous to the findings with E2, these changes result in a change in charge and are found near a glycosylation site at residue 139. This domain of E1 may therefore be found near the 181 to 216 domain of E2 on the surface of the E1-E2 heterodimer; together, they could form a domain important in virus penetration and neutralization.     

Epitope-specific antibody response to murine hepatitis virus-4 (strain JHM)

Monoclonal hybridoma antibodies to the structural proteins of murine hepatitis virus-4, strain JHM (MHV-4) were used in a competition binding enzyme immunoassay to analyze at the epitope level the antibody response of mice after infection with MHV-4. Colonized mice often had pre-existing MHV antibodies directed against epitopes on the E2 glycoprotein, the E1 glycoprotein, and the nucleocapsid protein. These mice generated a secondary antibody response after virus inoculation, reaching peak levels 7 days after infection. In contrast, Nude/+ mice raised in a pathogen-free colony had no detectable circulating MHV antibodies and generated a primary antibody response which gradually increased to peak levels 14 to 28 days after infection. Kinetics of antibody responses against specific epitopes usually correlated well with measured total virus-specific antibody responses, but variation was observed. Mice injected with three antigenically distinct strains of MHV made antibody responses to conserved epitopes but not to an antigenic determinant absent in these strains. Measurement of epitope-specific responses in a polyclonal population of viral specific antibodies is feasible and a valuable adjunct in understanding viral immunity.     

Antigenic and functional organization of human parainfluenza virus type 3 fusion glycoprotein.

Twenty-six monoclonal antibodies (MAbs) (14 neutralizing and 12 nonneutralizing) were used to examine the antigenic structure, biological properties, and natural variation of the fusion (F) glycoprotein of human type 3 parainfluenza virus (PIV3). Analysis of laboratory-selected antigenic variants and of PIV3 clinical isolates indicated that the panel of MAbs recognizes at least 20 epitopes, 14 of which participate in neutralization. Competitive binding assays indicated that the 14 neutralization epitopes are organized into three nonoverlapping antigenic sites (A, B, and C) and one bridge site (AB) and that the 6 nonneutralization epitopes form four sites (D, E, F, and G). Most of the neutralizing MAbs were involved in nonreciprocal competitive binding reactions, suggesting that they induce conformational changes in other neutralization epitopes. Fusion-inhibition and complemented-enhanced neutralization assays indicated that antigenic sites AB, B, and C may correspond to functional domains of the F molecule. Our results indicated that antibody binding alone is not sufficient for virus neutralization and that many anti-F MAbs neutralize by mechanisms not involving fusion-inhibition. The degree of antigenic variation in the F epitopes of clinical strains was examined by binding and neutralization tests. It appears that PIV3 frequently develops mutations that produce F epitopes which efficiently bind antibodies, but are completely resistant to neutralization by these antibodies.     

Heterogeneity of apolipoprotein E epitope expression on human lipoproteins: importance for apolipoprotein E function

The conformations of apolipoproteins on the surfaces of lipoprotein particles affect their physiologic functions. The conformations of apoE on plasma lipoproteins were examined using a panel of eight anti-apoE monoclonal antibodies (MAbs). The antibodies, which reacted with the major isoforms of apoE (E2, E3, and E4), defined at least five epitopes on apoE. Proteolytic fragments and synthetic peptides of apoE were used in binding assays to assign antibody epitopes; the epitopes were all localized to the middle third of the apoE molecule. The expression of apoE epitopes on isolated apoE and on lipoproteins was probed in competitive microtiter plate immunoassays using the anti-apoE MAbs, 125I-labeled apoE as tracer, and isolated apoE, intermediate density (IDL), very low density (VLDL1-3), and high density (HDL2 and HDL3) lipoproteins as competitors. The antibodies determined the patterns of competition exhibited by the lipoprotein preparations. Antibodies of the IgM class (WU E-1, WU E-2, WU E-3) defined two sets of conformation-dependent epitopes that were assigned towards the middle and the carboxyl terminal of the middle third of apoE. Competition curves using these antibodies, apoE, and lipoproteins showed a large variability in ED50 values. MAbs WU E-4, WU E-7, and WU E-10 defined epitopes near the receptor recognition site on apoE. Competition curves demonstrated small ranges of ED50 values. MAbs WU E-11 and WU E-12, which defined epitopes toward the amino-terminal region of apoE, exhibited competition curves for apoE and lipoproteins that had consistent, but wider ranges of ED50 values. There was no strict relationship between lipoprotein flotation rates and epitope expression for any of the MAbs. Immunoaffinity chromatography of VLDL subfractions on four different MAb columns indicated that the differences in the competitive abilities of VLDL subfractions were partly due to heterogeneity of apoE epitope expression within any population of particles. VLDL particles specifically retained on two different anti-apoE MAb columns were better competitors than unretained fractions for 125I-labeled LDL binding to the apoB, E-receptor of cultured human fibroblasts, suggesting that increased accessibility of apoE on the surface of VLDL is associated with increased receptor recognition. These data suggest that individual epitopes of apoE can be modulated; epitope expressions are not determined solely by the sizes and/or densities of lipoprotein particles; and differences in apoE conformation have significant metabolic consequences.     

Marked differences in the antigenic structure of human respiratory syncytial virus F and G glycoproteins.

Monoclonal antibodies directed against the glycoproteins of human respiratory syncytial virus were used in competitive enzyme-linked immunosorbent assays for topological mapping of epitopes. Whereas epitopes of the F glycoprotein could be ascribed to five nonoverlapping antigenic sites, anti-G antibodies recognized unique epitopes, many of whose competition profiles overlapped extensively. Variant viruses selected with a neutralizing (47F) anti-F antibody lost the binding for only 47F and 49F antibodies, which mapped in the same antigenic area. In contrast, viruses selected with an anti-G antibody lost the capacity to bind most of the anti-G antibodies, and their G protein was not recognized by an anti-virus antiserum, indicating major changes in the antigenic structure of the G molecule. Finally, we found great antigenic variation of the G protein among viral isolates. This occurred even within viruses of the same subtype with only limited divergence of amino acid sequence between strains. All of these data indicate marked differences in the antigenic organization of the G and F glycoproteins of respiratory syncytial virus; we discuss these differences in terms of the chemical structure of the glycoproteins.     

Detailed mapping of the antigenicity of the surface unit glycoprotein of equine infectious anemia virus by using synthetic peptide strategies.

We describe here a detailed analysis of the antigenic determinants of the surface unit glycoprotein (gp90) of equine infectious anemia virus (EIAV), using a comprehensive panel of synthetic peptides in enzyme-linked immunosorbent assays with immune serum from naturally and experimentally infected horses and with a panel of gp90-specific neutralizing and nonneutralizing monoclonal antibodies. The results of these studies identify immunoreactive segments throughout the conserved and variable domains of gp90 but localize immunodominant (100% reactivity) determinants to the amino and carboxyl termini of the glycoprotein molecule. Analysis of peptide reactivities with longitudinal serum samples taken from experimentally infected ponies revealed that antibody responses to conserved B-cell determinants appeared earlier and at higher titers than do antibodies specific for determinants contained in the variable domain of gp90. These observations suggest an evolution of antibody responses in EIAV-infected ponies that may correspond to the establishment of immunological control of virus replication and disease routinely observed in EIAV infections. In addition, the mapping of monoclonal antibody epitopes to peptides of 9 to 12 amino acids demonstrated that all of the neutralizing epitopes are located in the variable domain of gp90. The arrangement of neutralizing epitopes and critical structural considerations suggest that EIAV gp90 contains a principal neutralizing domain similar to the V3 loop of human immunodeficiency virus type 1. These antigenic analyses provide an important foundation for further analyzing the protective immune response generated during persistent EIAV infections and also provide potential peptide substrates for diagnostic assays and for vaccine strategies.     

猪瘟病毒糖蛋白E^rns中和表位的鉴定和比较

猪瘟病毒 (CSFV)囊膜结构糖蛋白Erns(gp4 8)是诱导机体产生中和抗体及激发保护性免疫应答的第二抗原蛋白。E2和Erns与细胞表面受体的相互作用介导CSFV感染细胞的过程。Erns具有RNA酶活性 ,影响病毒自身复制并涉及对病毒的中和效应。采用抗CSFValfortT櫣ｂｉｎｇｅｎ毒株Ｅｒｎｓ糖蛋白的 1B5 ,b4_2 2和 2 4 16单克隆中和抗体 ,筛选噬菌体展示的 12肽随机肽库 ,进行Erns中和表位的鉴定和比较 ,获得分别针对 1B5、b4_2 2和 2 4 16单克隆抗体的 3个主要中和表 (拟 )位基序WxNxxP、DKNR (Q)G和A(T)CxYxKN ,分别定位于Erns的 35 1位～ 35 6位或 348位～ 35 0位、384位～ 386及 32 2位～ 32 3位、380位～ 386位氨基酸区域。分析表 (拟 )位基序与单克隆抗体的免疫反应性差异。b4_2 2和 2 4 16单克隆抗体识别基序存在共有序列KN ,识别Erns中的相似抗原区 ,但其侧翼序列及免疫印迹、免疫荧光抗体抑制试验结果均存在显著差异     

Passive immune protection by herpes simplex virus-specific monoclonal antibodies and monoclonal antibody-resistant mutants altered in pathogenicity.

Virus-neutralizing monoclonal antibodies specific for 13 different genetically defined epitopes of glycoproteins gC, gB, and gD of herpes simplex virus type 1, strain KOS-321, were compared for their ability to provide passive immunity to DBA-2 mice challenged intracranially. Protection was highly specific, since individual monoclonal antibodies failed to protect against infection with monoclonal antibody-resistant (mar) mutants altered in the single epitope recognized by the injected antibody. The dose-response kinetics of passive immunity paralleled the in vitro neutralization titers for each antibody. No correlation was observed between immune protection and antibody isotype or complement-dependent in vitro neutralization titers. This suggests that virus neutralization was not the protective mechanism. In general, antibodies reactive with epitopes of gC were protective at the lowest antibody doses, antibodies specific for gB were less efficient in providing immunity, and antibodies against gD were the least effective. mar mutants with single epitope changes in gC and multiple epitope changes in gB showed highly reduced pathogenicity, requiring up to 5 X 10(6) PFU to kill 50% of infected animals. These findings indicated that antigenic variation affects virus growth and spread in the central nervous system. Thus, mutations which affect antigenic structure also can alter virus pathogenicity. The alteration of these epitopes does not, however, appreciably reduce the development of resistance to infection. Infection of mice with these mutants or inoculation of mice with UV-inactivated, mutant-infected cells before challenge rendered the animals resistant to infection with wild-type herpes simplex virus type 1.     

Antibody responses of humans and nonhuman primates to individual antigenic sites of the hemagglutinin-neuraminidase and fusion glycoproteins after primary infection or reinfection with parainfluenza type 3 virus.

An unusual feature of human parainfluenza virus type 3 (PIV3) is ita ability to cause reinfection with high efficiency. The antibody responses of 45 humans and 9 rhesus monkeys to primary infection or subsequent reinfection with PIV3 were examined to identify deficiencies in host immunologic responses that might contribute to the ability of the virus to cause reinfection with high frequency. Antibody responses in serum were tested by using neutralization and hemagglutination inhibition (HI) assays and a monoclonal antibody blocking immunoassay able to detect antibodies to epitopes within six antigenic sites on the PIV3 hemagglutinin-neuraminidase (HN) glycoprotein and eight antigenic sites on the fusion (F) protein. Primary infection of seronegative infants or children with PIV3 stimulated strong and rather uniform HI and neutralizing antibody responses. More than 90% of the individuals developed antibodies to four of the six HN antigenic sites (including three of the four neutralization sites), but the responses to F antigenic sites were of lesser magnitude and varied considerably from person to person. Young infants who possessed maternally derived antibodies in their sera developed lower levels and less frequent HI, neutralizing, and antigenic site-specific responses to the HN and F glycoproteins than did seronegative infants and children. In contrast, children reinfected with PIV3 developed even higher HI and neutralizing antibody responses than those observed during primary infection. Reinfection broadened the HN and F antigenic site-specific responses, but the latter remained relatively restricted. Adults possessed lower levels of HI, neutralizing, and antigenic site-specific antibodies in their sera than did children who had been reinfected, suggesting that these antibodies decay with time. Rhesus monkeys developed more vigorous primary and secondary antibody responses than did humans, but even in these highly responsive animals, response to the F glycoprotein was relatively restricted following primary infection. Bovine PIV3 induced a broader response to human PIV3 in monkeys than was anticipated on the basis of their known relatedness as defined by using monoclonal antibodies to human PIV3. These observations suggest that the restricted antibody responses to multiple antigenic sites on the F glycoprotein in young seronegative infants and children and the decreased responses to both the F and HN glycoproteins in young infants and children with maternally derived antibodies may play a role in the susceptibility of human infants and young children to reinfection with PIV3.     

Characterization of an immunodominant antigenic site on GB virus C glycoprotein E2 that is involved in cell binding

GB virus type C (GBV-C) is a human flavivirus that may cause persistent infection, although most infected individuals clear viremia and develop antibodies to the envelope glycoprotein E2. To study GBV-C E2 antigenicity and cell binding, murine anti-E2 monoclonal antibodies (MAbs) were evaluated to topologically map immunogenic sites on GBV-C E2 and for the ability to detect or block recombinant E2 binding to various cell lines. Five competition groups of MAbs were identified. Groups I and II did not compete with each other. Group III competed with both groups I and II. Group IV did not compete with group I, II, or III. One MAb competed with all of the other MAbs, suggesting that the epitopes bound by these MAbs are intimately related. Individually, none of the MAbs competed extensively with polyclonal human convalescent antibody (PcAb); however, combinations of all five MAb groups completely blocked PcAb binding to E2, suggesting that the epitopes bound by these MAbs form a single, immunodominant antigenic site. Only group I and III MAbs detected purified recombinant E2 bound to cells in binding assays. In contrast, group II MAbs neutralized the binding of E2 to cells. Both PcAb and MAbs were conformation dependent, with the exception of one group II MAb (M6). M6 bound to a five-amino-acid sequence on E2 if the peptide included four C-terminal or eight N-terminal residues, suggesting that the GBV-C E2 protein contains a single immunodominant antigenic site which includes a complex epitope that is involved in specific cellular binding.     

Characterization of the structural proteins of the murine coronavirus strain A59 using monoclonal antibodies

Monoclonal antibodies reacting with the A59 strain of mouse hepatitis virus (MHV-A59) were characterized and those specific to the E2 major envelope glycoprotein were studied in detail. Antibodies were tested for their ability to neutralize viral infectivity (N+ characteristic) and prevent viral-induced cell-to-cell fusion (F+ characteristic). All four possible combinations of activities reflecting E2 functions were found, i.e., N+F+, N-F-, N+F-, and N-F+. In addition, competitive binding studies with these monoclonal antibodies revealed two nonoverlapping antigenic regions. The first region, designated A, was recognized by antibodies which included each of the four functional types. Region B was identified by a single monoclonal antibody with N-F- activities. The existence of antibodies which only neutralize virus or only block viral-induced fusion implies that the structures on E2 which serve as targets for neutralization and which induce fusion are not identical. The critical determinants for neutralization and fusion must be closely related topographically on E2 since both N+F- and N-F+ antibodies recognize the same antigenic region.     

Identification of two epitopes in the carboxyterminal 15 amino acids of the E1 glycoprotein of mouse hepatitis virus A59 by using hybrid proteins.

cDNA fragments coding for the carboxy terminus of the E1 envelope glycoprotein from mouse hepatitis virus A59, a coronavirus, were cloned into the bacterial expression vector pEX. Clones expressing E1 antigenic determinants were selected with a polyclonal anti-E1 antibody and used for immunization of rabbits and for affinity purification of existing polyclonal antisera. Immunofluorescence testing and immunoperoxidase labeling of coronavirus-infected cells showed that these reagents were monospecific for E1. In addition, by using hybrid proteins containing different lengths of the E1 carboxy terminus to affinity-purify a polyclonal antiserum against E1, we have been able to define two epitopes within the last 15 amino acid residues of the protein. These epitope-specific antibodies bind to E1 in Golgi and perinuclear membranes as well as to budding viruses; they do not, however, label the plasma membrane or the membranes of post-Golgi vesicles transporting virions to the cell surface.     

Human Monoclonal Antibodies to a Novel Cluster of Conformational Epitopes on HCV E2 with Resistance to Neutralization Escape in a Genotype 2a Isolate

The majority of broadly neutralizing antibodies to hepatitis C virus (HCV) are against conformational epitopes on the E2 glycoprotein. Many of them recognize overlapping epitopes in a cluster, designated as antigenic domain B, that contains residues G530 and D535. To gain information on other regions that will be relevant for vaccine design, we employed yeast surface display of antibodies that bound to genotype 1a H77C E2 mutant proteins containing a substitution either at Y632A (to avoid selecting non-neutralizing antibodies) or D535A. A panel of nine human monoclonal antibodies (HMAbs) was isolated and designated as HC-84-related antibodies. Each HMAb neutralized cell culture infectious HCV (HCVcc) with genotypes 1–6 envelope proteins with varying profiles, and each inhibited E2 binding to the viral receptor CD81. Five of these antibodies neutralized representative genotypes 1–6 HCVcc. Epitope mapping identified a cluster of overlapping epitopes that included nine contact residues in two E2 regions encompassing aa418–446 and aa611–616. Effect on virus entry was measured using H77C HCV retroviral pseudoparticles, HCVpp, bearing an alanine substitution at each of the contact residues. Seven of ten mutant HCVpp showed over 90% reduction compared to wild-type HCVpp and two others showed approximately 80% reduction. Interestingly, four of these antibodies bound to a linear E2 synthetic peptide encompassing aa434–446. This region on E2 has been proposed to elicit non-neutralizing antibodies in humans that interfere with neutralizing antibodies directed at an adjacent E2 region from aa410–425. The isolation of four HC-84 HMAbs binding to the peptide, aa434–446, proves that some antibodies to this region are to highly conserved epitopes mediating broad virus neutralization. Indeed, when HCVcc were passaged in the presence of each of these antibodies, virus escape was not observed. Thus, the cluster of HC-84 epitopes, designated as antigenic domain D, is relevant for vaccine design for this highly diverse virus.     

Localization of epitopes of herpes simplex virus type 1 glycoprotein D.

We previously defined eight groups of monoclonal antibodies which react with distinct epitopes of herpes simplex virus glycoprotein D (gD). One of these, group VII antibody, was shown to react with a type-common continuous epitope within residues 11 to 19 of the mature glycoprotein (residues 36 to 44 of the predicted sequence of gD). In the current investigation, we have localized the sites of binding of two additional antibody groups which recognize continuous epitopes of gD. The use of truncated forms of gD as well as computer predictions of secondary structure and hydrophilicity were instrumental in locating these epitopes and choosing synthetic peptides to mimic their reactivity. Group II antibodies, which are type common, react with an epitope within residues 268 to 287 of the mature glycoprotein (residues 293 to 312 of the predicted sequence). Group V antibodies, which are gD-1 specific, react with an epitope within residues 340 to 356 of the mature protein (residues 365 to 381 of the predicted sequence). Four additional groups of monoclonal antibodies appear to react with discontinuous epitopes of gD-1, since the reactivity of these antibodies was lost when the glycoprotein was denatured by reduction and alkylation. Truncated forms of gD were used to localize these four epitopes to the first 260 amino acids of the mature protein. Competition experiments were used to assess the relative positions of binding of various pairs of monoclonal antibodies. In several cases, when one antibody was bound, there was no interference with the binding of an antibody from another group, indicating that the epitopes were distinct. However, in other cases, there was competition, indicating that these epitopes might share some common amino acids.     

Identification of amino acids recognized by syncytium-inhibiting and neutralizing monoclonal antibodies to the human parainfluenza type 3 virus fusion protein.

Neutralizing monoclonal antibodies specific for the fusion (F) glycoprotein of human parainfluenza type 3 virus (PIV3) were used to select neutralization-resistant antigenic variants. Sequence analysis of the F genes of the variants indicated that their resistance to antibody binding, antibody-mediated neutralization or to both was a result of specific amino acid substitutions within the neutralization epitopes of the F1 and F2 subunits. Comparison of the locations of PIV3 neutralization epitopes with those of Newcastle disease and Sendai viruses indicated that the antigenic organization of the fusion proteins of paramyxoviruses is similar. Furthermore, some of the PIV3 epitopes recognized by syncytium-inhibiting monoclonal antibodies are located in an F1 cysteine cluster region which corresponds to an area of the measles virus F protein involved in fusion activity.     

Peptide immunogen mimicry of putative E1 glycoprotein-specific epitopes in hepatitis C virus.

Hepatitis C virus (HCV) accounts for most cases of acute and chronic non-A and non-B hepatitis with serious consequences that may lead to hepatocellular carcinoma. The putative envelope glycoproteins (E1 and E2) of HCV probably play a role in the pathophysiology of the virus. In order to map the immunodominant domains of the E1 glycoprotein, two epitopes from amino acid residues 210 to 223 (P1) and 315 to 327 (P2) were predicted from the HCV sequence. Immunization of mice with the synthetic peptides conjugated to bovine serum albumin induced an antibody response, and the antisera immunoprecipitated the E1 glycoprotein (approximately 33 kDa) of HCV expressed by recombinant vaccinia virus. A panel of HCV-infected human sera was also tested with the synthetic peptides by enzyme-linked immunosorbent assay for epitope-specific responses. Of 38 infected serum samples, 35 (92.1%) demonstrated a spectrum of reactivity to the P2 peptide. On the other hand, only 17 of 38 (44.7%) serum samples were reactive to the P1 peptide. Strains of HCV exhibit a striking genomic diversity. The predicted P1 epitope showed localization in the sequence-variable region, and the P2 epitope localized in a highly conserved domain. Results from this study suggest that the E1 glycoprotein of HCV contains at least two potential antigenic epitopes. Synthetic peptides corresponding to these epitopes and antisera to these peptides may serve as the monospecific immunological reagents to further determine the role of E1 glycoprotein in HCV infection.