Immunoglobulin G(Fc)-binding receptors on virions of herpes simplex virus type 1 and transfer of these receptors to the cell surface by infection

We have found that virions of herpes simplex virus type 1 have surface receptors capable of binding to the Fc region of immunoglobulin G and have also shown that the previously identified Fc-binding glycoprotein (designated gE) is present in extracts prepared from purified virions. The technique of affinity chromatography was used to detect gE. Two approaches were used to demonstrate the presence of Fc-binding receptors on intact virions. First, it was shown that [125I]-immunoglobulin G, but not [125I]F(ab')2 fragments, cosedimented with virions in sucrose gradients and, second, electron microscopy was done to show that soluble peroxidase-antiperoxidase complexes bound to virions. The use of peroxidase-antiperoxidase complexes also permitted us to demonstrate that Fc-binding receptors from input (parental) virions become incorporated into the surface membranes of infected cells. This occurs presumably as a consequence of fusion between the virion envelope and cell surface membrane.     

Similarities and differences in the Fc-binding glycoprotein (gE) of herpes simplex virus types 1 and 2 and tentative mapping of the viral gene for this glycoprotein.

We performed affinity chromatography and immunoprecipitation experiments to determine whether cells infected with herpes simplex virus type 2 (HSV-2) expressed a glycoprotein that was functionally and antigenically related to the HSV-1 Fc-binding glycoprotein designated gE. We found that a protein from extracts of HSV-2-infected HEp-2 cells bound specifically to an Fc affinity column and that the electrophoretic mobility of this protein in sodium dodecyl sulfate-acrylamide gels was slightly less than the mobility of HSV-1 gE. Immunoprecipitation experiments performed with an antiserum prepared against HSV-1 gE revealed that (i) extracts from HSV-2-infected cells contained a glycoprotein that was antigenically related to HSV-1 gE; (ii) the electrophoretic mobility of the HSV-2 gE was indistinguishable from the mobility of the HSV-2 Fc-binding protein; (iii) the antiserum reacted with both newly synthesized transient forms and stable fully processed forms of both HSV-1 gE and HSV-2 gE; and (iv) the transient and stable forms of HSV-2 gE all had lower electrophoretic mobilities than their HSV-1 counterparts. Electrophoretic analyses of gE precipitated from extracts of HEp-2 cells infected with two sets of HSV-1 x HSV-2 intertypic recombinant viruses suggested that the gene for gE is located at the right end of the HSV genome (0.85 to 0.97 map units) in the unique portion of the S component.     

Glycoprotein gE of herpes simplex virus type 1: effects of anti-gE on virion infectivity and on virus-induced fc-binding receptors.

An Fc-binding glycoprotein, designated gE, was detected previously in cells infected with herpes simplex virus type 1 (HSV-1) and in virion preparations isolated from infected cells. For the studies reported here, we purified gE from HSV-1 strain HFEM(syn) by affinity chromatography and preparative electrophoresis and then immunized a rabbit to produce an antiserum to glycoprotein gE. We found that this antiserum selectively precipitated gE and its precursors from detergent-solubilized extracts of HSV-1 strain HFEM(syn)-infected HEp-2 cells, from extracts of other cell lines infected with the same virus, and from extracts of HEp-2 cells infected with several other HSV-1 strains. The antiserum did not precipitate any proteins from uninfected cells. The several forms of gE detected by immunoprecipitation accumulated in variable quantities in different cells infected with the different virus strains and also varied slightly with respect to electrophoretic mobility, suggesting some differences in the gE's from different HSV-1 strains and some effects of the host cell on the nature and extent of post-translational processing. One of the electrophoretic forms of gE previously detected in purified preparations of virions could be precipitated by anti-gE from extracts of purified HSV-1 strain HFEM(syn) virions. Moreover, anti-gE neutralized HSV-1 infectivity, but only in the presence of complement. Finally, F(ab')2 fragments of the anti-gE immunoglobulin partially inhibited the binding of 125I-labeled immunoglobulin G to the Fc receptors on HSV-1-infected cells.     

Identification of a novel herpes simplex virus type 1-induced glycoprotein which complexes with gE and binds immunoglobulin.

We detected a glycoprotein on the surface of cells infected with herpes simplex virus type 1 (HSV-1) which, in conjunction with gE, binds immunoglobulin G (IgG). The novel glycoprotein, which has an apparent molecular mass of 70 kilodaltons and was provisionally named g70, was first detected in extracts of HSV-1-infected cells labeled by lactoperoxidase-catalyzed iodination and precipitated with rabbit sera or IgG and protein A-Sepharose. In subsequent experiments, g70 and gE were coprecipitated from extracts of HSV-1-infected cells labeled with [35S]methionine, [35S]cysteine, or 14C-amino acids. We were unable to precipitate a polypeptide analogous to g70 or gE from extracts of HSV-2-infected cells with rabbit IgG and protein A-Sepharose. Partial proteolytic peptide analysis indicated that g70 is structurally distinct from gE and gI). In addition, g70 was electrophoretically distinct from the HSV-1 Us4 glycoprotein gG. HSV-1 gE, expressed in mouse cells transfected with the gE gene, was not precipitated with rabbit IgG, nor could these cells bind radiolabeled IgG, suggesting that gE alone cannot act as an IgG (Fc) receptor. This result, coupled with the findings that gE and g70 are coprecipitated with IgG and with an anti-gE monoclonal antibody, suggests that gE and g70 form a complex which binds IgG. The electrophoretic mobilities of g70 molecules induced by different strains of HSV-1 differed markedly, arguing that g70 is encoded by the virus and is not a cellular protein induced by virus infection.     

Use of monoclonal antibodies against two 75,000-molecular-weight glycoproteins specified by herpes simplex virus type 2 in glycoprotein identification and gene mapping

We produced two monoclonal antibodies that precipitate different glycoproteins of similar apparent molecular weight (70,000 to 80,000) from extracts of cells infected with herpes simplex virus type 2. Evidence is presented that one of these glycoproteins is the previously characterized glycoprotein gE, whereas the other maps to a region of the herpes simplex virus type 2 genome collinear with the region in herpes simplex virus type 1 DNA that encodes gC.     

Induction of immunoglobulin G Fc receptors by recombinant vaccinia viruses expressing glycoproteins E and I of herpes simplex virus type 1.

Glycoprotein E (gE) of herpes simplex virus type 1 (HSV-1) will bind immunoglobulin G (IgG) (Fc) affinity columns (R. B. Bauke and P. G. Spear, J. Virol. 32:779-789, 1979), but recent evidence suggests that the HSV-1 Fc receptor is composed of a complex of gE and glycoprotein I (gI) and that both gI and gE are required for Fc receptor activity (D. C. Johnson and V. Feenstra, J. Virol. 61:2208-2216, 1987; D. C. Johnson, M. C. Frame, M. W. Ligas, A. M. Cross, and N. D. Stow, J. Virol. 62:1347-1354, 1988). We have expressed gE and gI, either alone or in combination, on the surface of HeLa cells by using recombinant vaccinia viruses and have measured Fc receptor activity by Fc-rosetting or IgG-binding assays. Expression of gE alone resulted in the induction of Fc receptor activity, while expression of gI alone gave no detectable Fc binding. Coexpression of gE and gI resulted in higher levels of IgG binding than did expression of gE alone, despite the fact that under conditions of coexpression, the levels of surface gE were reduced. We propose that gE and gI together form a receptor of higher affinity than gE alone and that HSV-1 therefore has the potential to induce two Fc receptors of different affinities.     

Specificities of monoclonal and polyclonal antibodies that inhibit adsorption of herpes simplex virus to cells and lack of inhibition by potent neutralizing antibodies.

Polyclonal and monoclonal antibodies to individual herpes simplex virus (HSV) glycoproteins were tested for ability to inhibit adsorption of radiolabeled HSV type 1 (HSV-1) strain HFEMsyn [HSV-1(HFEM)syn] to HEp-2 cell monolayers. Polyclonal rabbit antibodies specific for glycoprotein D (gD) or gC and three monoclonal mouse antibodies specific for gD-1 or gC-1 most effectively inhibited HSV-1 adsorption. Antibodies of other specificities had less or no inhibitory activity despite demonstrable binding of the antibodies to virions. Nonimmune rabbit immunoglobulin G and Fc fragments partially inhibited adsorption when used at relatively high concentrations. These results suggest involvement of gD, gC, and perhaps gE (the Fc-binding glycoprotein) in adsorption. The monoclonal anti-gD antibodies that were most effective at inhibiting HSV-1 adsorption had only weak neutralizing activity. The most potent anti-gD neutralizing antibodies had little effect on adsorption at concentrations significantly higher than those required for neutralization. This suggests that, although some anti-gD antibodies can neutralize virus by blocking adsorption, a more important mechanism of neutralization by anti-gD antibodies may be interference with a step subsequent to adsorption, possibly penetration.     

Crystal structure of the HSV-1 Fc receptor bound to Fc reveals a mechanism for antibody bipolar bridging

Herpes simplex virus type-1 expresses a heterodimeric Fc receptor, gE-gI, on the surfaces of virions and infected cells that binds the Fc region of host immunoglobulin G and is implicated in the cell-to-cell spread of virus. gE-gI binds immunoglobulin G at the basic pH of the cell surface and releases it at the acidic pH of lysosomes, consistent with a role in facilitating the degradation of antiviral antibodies. Here we identify the C-terminal domain of the gE ectodomain (CgE) as the minimal Fc-binding domain and present a 1.78-Å CgE structure. A 5-Å gE-gI/Fc crystal structure, which was independently verified by a theoretical prediction method, reveals that CgE binds Fc at the C _H2-C _H3 interface, the binding site for several mammalian and bacterial Fc-binding proteins. The structure identifies interface histidines that may confer pH-dependent binding and regions of CgE implicated in cell-to-cell spread of virus. The ternary organization of the gE-gI/Fc complex is compatible with antibody bipolar bridging, which can interfere with the antiviral immune response.     

Herpes simplex virus type 1 glycoprotein E is not indispensable for viral infectivity.

A mutant of the herpes simplex virus type 1 Angelotti was isolated in which 87% of the coding region of glycoprotein E (gE) was deleted and replaced by a functional neomycin resistance gene of the Tn5 transposon. The mutant was characterized by restriction enzyme analyses and Southern blotting. Western blotting of proteins and immunofluorescence assays revealed that gE was completely absent and that the Fc receptor was not expressed in cells infected with the mutant. The fact that this mutant was viable and that it replicated to a slightly lower titer than did the wild-type virus suggests that the presence of gE is not a prerequisite of viral infectivity in tissue culture.     

Herpes simplex virus type 1 encodes two Fc receptors which have different binding characteristics for monomeric immunoglobulin G (IgG) and IgG complexes.

Two herpes simplex virus type 1 glycoproteins, gE and gI, have been shown to form a complex that binds the Fc domain of immunoglobulin G (IgG). We demonstrate that this complex is required for the binding of monomeric nonimmune IgG but that gE alone is sufficient for binding polymeric IgG in the form of IgG complexes. Evidence that gE but not gI is required for binding IgG complexes is as follows. IgG complexes bound equally well to cells infected with gI-negative mutants or with wild-type virus, whereas cells infected with gE-negative mutants did not bind IgG complexes. Furthermore, L cells transiently transfected to express gE bound IgG complexes. Additional evidence that gI fails to augment binding of IgG complexes comes from experiments in which the gI gene was inducibly expressed in cells after infection. Inducible gI expression failed to increase binding of IgG complexes to infected cells in comparison with cells not capable of inducible gI expression. In contrast, expression of both gE and gI was necessary for binding of monomeric IgG, as demonstrated by flow cytometry using cells infected with gE-negative and gI-negative mutants. These observations demonstrate that herpes simplex virus type 1 Fc receptors (FcRs) have different binding characteristics for monomeric IgG and IgG complexes. Furthermore, it appears that gE is the FcR for IgG complexes and that gE and gI form the FcR for monomeric IgG.     

Unusual lectin-binding properties of a herpes simplex virus type 1-specific glycoprotein

Lysates from herpes simplex virus type 1-infected cells were subjected to affinity chromatography on soybean and Helix pomatia lectins. One of the virus-specified glycoproteins, probably the herpes simplex virus type 1-specific gC glycoprotein, bound to the lectins and was eluted with N-acetylgalactosamine. The affinity chromatography permitted a high degree of purification of the type-specific glycoprotein with respect to both host cell components and other viral glycoproteins. The lectin affinity pattern of this glycoprotein indicates the presence of a terminal alpha-N-acetylgalactosamine in an oligosaccharide, a finding not reported previously for glycoproteins of enveloped viruses.     

Effect of tunicamycin on the synthesis of herpes simplex virus type 1 glycoproteins and their expression on the cell surface.

Herpes simplex virus specifies five glycoproteins which have been found on the surface of both the intact, infected cells and the virion envelope. In the presence of the drug tunicamycin, glycosylation of the herpes simplex virus type 1 glycoproteins is inhibited. We present in this report evidence that the immunologically specificity of the glycoproteins designated gA, gB, and gD resides mainly in the underglycosylated "core" proteins, as demonstrated by the immunoblotting technique. We showed also that tunicamycin prevented exposure of the viral glycoproteins on the cell surface, as the individual glycoproteins lost their ability to participate as targets for the specific antibodies applied in the antibody-dependent, cell-mediated cytotoxicity test. Immunocytolysis was reduced between 73 and 97%, depending on the specificity of the antibodies used. The intracellular processing of the herpes simplex virus type 1-specific glycoprotein designated gC differed from the processing of gA, gB, and GD, as evidenced by the identification of an underglycosylated but immunochemically modified form of gC on the surface of infected cells grown in the presence of tunicamycin.     

Synthesis, processing, and oligomerization of bovine herpesvirus 1 gE and gI membrane proteins.

This study reports the identification and initial characterization of the precursors, modified forms, and oligomers of bovine herpesvirus 1 (BHV-1) gI and gE proteins with polyvalent rabbit serum specific for gI or gE. Our experiments used the Colorado strain of BHV-1 and mutant viruses with insertions of the Escherichia coli lacZ gene into the predicted gE and gI reading frames. We also translated the gE and gI open reading frames in vitro and expressed them in uninfected cells using eukaryotic expression vectors. Precursor-product relationships were established by pulse-chase analysis and endoglycosidase H and glycopeptidase F digestions. Like the homologous glycoproteins of herpes simplex virus type 1, pseudorabies virus, and varicella-zoster virus, BHV-1 gI and gE are modified by N-linked glycosylation and associate with each other soon after synthesis, forming a noncovalent complex in infected and transfected cells. An analysis of mutant and wild-type-virus-infected cells and transfected COS cells expressing gE or gI alone suggested that gE-gI complex formation is necessary for efficient processing of the gE precursor to its mature form. One new finding was that unlike the other alphaherpesvirus gI homologs, a fraction of pulse-labeled gI synthesized in BHV-1-infected cells apparently is cleaved into two relatively stable fragments 2 to 4 h after the pulse. Finally, we incubated BHV-1-infected cell extracts with nonimmune mouse, rabbit, horse, pig, and calf sera and found no evidence that gE or gI functioned as Fc receptors as reported for the herpes simplex virus type 1 and varicella-zoster virus homologs.     

Nonstructural proteins of herpes simplex virus. I. Purification of the induced DNA polymerase.

Herpes simplex virus-induced DNA polymerase purified by published methods was found to be contaminated with many others proteins, including virus structural proteins. Thus, DEAE-cellulose and phosphocellulose chromatography were used in combination with affinity chromatography to purify DNA polymerase from herpes simplex virus type 1- and type 2-infected cells. The purified enzyme retained unique features of the herpesvirus-induced DNA polymerase, including a requirement for high salt concentrations for maximal activity, a sensitivity to low phosphonoacetate concentrations, and the capacity to be neutralized by rabbit antiserum to herpesvirus-infected cells. By polyacrylamide gel electrophoresis, the purified DNA polymerase was associated with a virus-induced polypeptide of about 150,000 molecular weight.     

Herpes simplex virus immunoglobulin G Fc receptor activity depends on a complex of two viral glycoproteins, gE and gI.

Evidence was recently presented that herpes simplex virus type 1 (HSV-1) immunoglobulin G (IgG) Fc receptors are composed of a complex containing a previously described glycoprotein, gE, and a novel virus-induced polypeptide, provisionally named g70 (D. C. Johnson and V. Feenstra, J. Virol. 61:2208-2216, 1987). Using a monoclonal antibody designated 3104, which recognizes g70, in conjunction with antipeptide sera and virus mutants unable to express g70 or gE, we have mapped the gene encoding g70 to the US7 open reading frame of HSV-1 adjacent to the gE gene. Therefore, g70 appears to be identical to a recently described polypeptide which was named gI (R. Longnecker, S. Chatterjee, R. J. Whitley, and B. Roizman, Proc. Natl. Acad. Sci. USA 84:147-151, 1987). Under mildly denaturing conditions, monoclonal antibody 3104 precipitated both gI and gE from extracts of HSV-1-infected cells. In addition, rabbit IgG precipitated the gE-gI complex from extracts of cells transfected with a fragment of HSV-1 DNA containing the gI, gE, and US9 genes. Cells infected with mutant viruses which were unable to express gE or gI did not bind radiolabeled IgG; however, cells coinfected with two viruses, one unable to express gE and the other unable to express gI, bound levels of IgG approaching those observed with wild-type viruses. These results further support the hypothesis that gE and gI form a complex which binds IgG by the Fc domain and that neither polypeptide alone can bind IgG.     

Galactose-rich glycoproteins are on the cell surface of herpes virus-infected cells. 1. Surface labeling and serial lectin binding studies of Asn-linked oligosaccharides of glycoprotein gC

Cell-surface glycoproteins of mock-infected and herpes simplex virus type 1 (HSV-1)-infected BHK-21 and HEp-2 cells were radiolabeled by incubation with galactose oxidase followed by reduction with NaB3H4. The incorporation of radiolabel into glycoconjugates in both BHK-21 and HEp-2 cells was increased several fold following infection with HSV, showing an increase in surface-exposed Gal residues in the infected cells. This was further confirmed by an increase in binding of cell-surface-labeled glycoproteins gC and gB from HSV-infected BHK-21 cells to Ricinus communis agglutinin I, which is specific for beta-D-Gal residues. Prior treatment of cells with Clostridium perfringens neuraminidase enhanced the surface radiolabeling by the galactose oxidase/NaB3H4 method: HEp-2 cells exhibited over sixfold enhancement in labeling, while BHK-21 cells showed only a slight increase. HSV glycoprotein gC was the predominant cell-surface glycoprotein radiolabeled by the galactose oxidase/NaB3H4 method in virus-infected BHK-21 cells. The glycoprotein gC was purified by immunoaffinity column chromatography on monoclonal anti-gC-antibody-Sepharose. The radiolabel in the glycopeptides of gC was resistant to beta elimination, showing that it was associated only with Asn-linked oligosaccharides. A serial lectin affinity chromatography of glycopeptides on columns of concanavalin A-Sepharose, lentil (Lens culinaris) lectin-Sepharose, and Ricin I-agarose allowed the assignment of minimal oligosaccharide structures bearing terminal Gal residues in gC.     

Antigenic cross-reactions among herpes simplex virus types 1 and 2, Epstein-Barr virus, and cytomegalovirus.

Polyvalent rabbit antisera against herpes simplex virus type 1 and 2 (HSV-1 and HSV-2), cytomegalovirus (CMV), and Epstein-Barr virus (EBV), monospecific antisera against affinity-purified HSV-2 glycoproteins gB and gG, and a panel of monoclonal antibodies against HSV and EBV proteins were used to analyze cross-reactive molecules in cells infected with the four herpesviruses. A combination of immunoprecipitation and Western blotting with these reagents was used to determine that all four viruses coded for a glycoprotein that cross-reacted with HSV-1 gB. CMV coded for proteins that cross-reacted with HSV-2 gC, gD, and gE. Both CMV and EBV coded for proteins that cross-reacted with HSV-2 gG. Antigenic counterparts to the p45 nucleocapsid protein of HSV-2 were present in HSV-1 and CMV, and counterparts of the major DNA-binding protein and the ribonucleotide reductase of HSV-1 were present in all the viruses. The EBV virion glycoprotein gp85 was immunoprecipitated by antisera to HSV-1, HSV-2, and CMV. Antisera to CMV and EBV neutralized the infectivity of both HSV-1 and HSV-2 at high concentrations. This suggests that cross-reactivity between these four human herpesviruses may have pathogenic as well as evolutionary significance.     

Possible Relationship between Bacterial or Viral Fcγ-Binding Proteins and Rheumatoid Factor

Bacterial Fc-binding proteins (FcBPs) such as staphylococcal protein A and streptococcal protein G possess IgG fine specificity strikingly similar to that of rheumatoid factors (RFs) derived from patients with rheumatoid arthritis (RA). They were shown to bind to the C_H2-C_H3 interface region of IgG. It has also been shown that peripheral blood lymphocytes can be selectively induced to produce RF by protein A. Several hypotheses, including idiotypic mimicry, have been proposed to explain the relationship of RF and bacterial FcBPs. Although convincing evidence for the involvement of bacterial infection in the etiology of RA has not been available, viral infection has frequently been strongly suspected as the agent possibly triggering RA. Herpes family viruses possess FcBPs reacting with the same C_H2-C_H3 interface region of IgG. Fab fragments of monoclonal antibodies (II-481, 88-S) to the IgG-bindlng site of glycoprotein E (gE), the FcBP glycoprotein of herpes simplex viruses, showed strong binding to RF. The epitope on gE reacting with mAb II-481 showed significant overlap with the IgG Fc-binding site. Antibodies to cytomegalovirus FcBP have been detected in a substantial proportion of sera from patients with RA. These observations may imply that some RFs may be produced as anti-idiotype antibodies to anti-viral FcBP antibodies. Thus, bacterial or viral FcBP could provide a link between RF production and a possible infectious etiology of RA.     

Characterization of the 92,000-dalton glycoprotein induced by herpes simplex virus type 2

Evidence is presented showing that the 92,000-dalton glycoprotein (g92K) induced by herpes simplex virus (HSV) type 2 has properties distinct from those assigned to any other HSV glycoprotein. First, the carbohydrate composition and extent of sulfation differ from those of glycoproteins D and E. Second, two clonally unrelated monoclonal antibodies, AP1 and LP5, shown in this paper to specifically immunoprecipitate g92K, do not react with any of the known processed forms of glycoproteins B, C, D, and E. Third, by using HSV type 1/HSV type 2 intertypic recombinants and a simple radioimmunoassay, the target antigen of the two monoclonal antibodies was shown to map in the same region as g92K (0.846 to 0.924). Fourth, the intertypic recombinant R12-3 was shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of infected cells to induce the HSV type 2 g92K and HSV type 1 gD and GE, whereas R12-1, which did not induce g92K, induced HSV-2 gE and an altered gD, providing genetic evidence that g92K is encoded, at least in part, by a different region of the genome from that encoding gD and gE.