B cell activation by cytomegalovirus.

Human cytomegalovirus is shown to be a nonspecific polyclonal B cell activator. The B cell response is independent of virus replication and requires little, if any, T cell help.

Epstein-barr virus regulates c-MYC, apoptosis, and tumorigenicity in Burkitt lymphoma.

Loss of the Epstein-Barr virus (EBV) genome from Akata Burkitt lymphoma (BL) cells is coincident with a loss of malignant phenotype, despite the fact that Akata and other EBV-positive BL cells express a restricted set of EBV gene products (type I latency) that are not known to overtly affect cell growth. Here we demonstrate that reestablishment of type I latency in EBV-negative Akata cells restores tumorigenicity and that tumorigenic potential correlates with an increased resistance to apoptosis under growth-limiting conditions. The antiapoptotic effect of EBV was associated with a higher level of Bcl-2 expression and an EBV-dependent decrease in steady-state levels of c-MYC protein. Although the EBV EBNA-1 protein is expressed in all EBV-associated tumors and is reported to have oncogenic potential, enforced expression of EBNA-1 alone in EBV-negative Akata cells failed to restore tumorigenicity or EBV-dependent down-regulation of c-MYC. These data provide direct evidence that EBV contributes to the tumorigenic potential of Burkitt lymphoma and suggest a novel model whereby a restricted latency program of EBV promotes B-cell survival, and thus virus persistence within an immune host, by selectively targeting the expression of c-MYC.

Diverse familial malignant tumors and Epstein-Barr virus.

Continued monitoring of a family for new malignant tumors has revealed diverse immunological and neoplastic disorders during a 15-year period. In 1966, the proband developed lymphoma. In 1975, his antibody titers to Epstein-Barr virus (EBV) became elevated, and again, he developed a malignant lymphoma. He also had borderline hypo-immunoglobulin A, died of glioblastoma multiforme in 1977, and at autopsy, had adenomatous colonic polyps. His eldest brother has normal immunoglobulin levels, but developed immune thrombocytopenia in 1973 and had elevated EBV antibody titers in 1980. Another brother had hypo-immunoglobulin A, thymoma in 1965, and adenomas and adenocarcinoma of the colon. Two other brothers succumbed to glioblastoma in 1968 and 1969. The father of the proband had bronchiectasis in 1952, hypo-immunoglobulin M documented in 1972, and elevated EBV antibody titers 5 years preceding development of a malignant lymphoma. The latter contained 10 EBV genome equivalents/cell by EBV viral DNA/DNA reassociation kinetics analysis. The proband's grandmother had died of an immunoglobulin G-secreting myeloma in 1977, and his grandfather had borderline low immunoglobulin M, elevated EBV antibody titers, and hypopharyngeal carcinoma in 1980. Predisposition to oncogenesis in this family was probably inherited.

Requirements for immunoglobulin synthesis in leukocyte cultures exposed to human cytomegalovirus.

T cell-depleted leukocytes from normal healthy donors lacking antibody to cytomegalovirus (CMV) were induced to secrete immunoglobulin (Ig) by exposure to inactivated CMV. The responses to two virus strains were compared. One strain had been reported to require specific T cell help to induce Ig synthesis, and the other had been reported to induce Ig synthesis in the presence of only very few cells. Both viruses induced T cell-depleted leukocytes from one group of seronegative donors to secrete Ig. However, both viruses failed to induce leukocytes from a second group of donors to secrete Ig unless B cell growth factor was added as a source of T cell help. These findings suggest that certain individuals are hyperresponsive to CMV and raise the possibility that this group may be most likely to develop mononucleosis after primary infection with CMV.

Proteins specified by bovine herpesvirus-2.

Polypeptides synthesized in bovine testes cells infected with bovine herpesvirus type 2 were labeled with [35S]methionine and were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Thirty-eight virus-induced proteins, ranging in molecular weight from 32,000 to 149,000, were detectable by analysis of whole cell lysates between postinfection hours 2 and 36. A similar number was immunoprecipitated by rabbit antiserum to bovine herpesvirus type 2. Twelve proteins incorporated [3H]glucosamine. On the basis of their temporal characteristics and their pattern of synthesis in the presence of cycloheximide and dactinomycin, 3 proteins, including at least one that was nondetectable in the absence of drugs, were classified as alpha proteins, 4 as beta proteins, 1 as a beta/gamma protein, and 27 as gamma proteins. Host cell protein synthesis was not reduced substantially until postinfection hours 22 to 28.

Epstein-Barr virus shed in saliva is high in B-cell-tropic glycoprotein gp42.

Epstein-Barr virus is an orally transmitted human herpesvirus that infects epithelial cells and establishes latency in memory B lymphocytes. Movement of virus between the two cell types is facilitated by changes in amounts of an envelope glycoprotein, gp42, which are effected by interaction of gp42 with HLA class II in a B cell. Here we used the differential ability of virus to bind to CD21-positive B cells and CD21-negative epithelial cells, which is also influenced by levels of gp42, to determine that the majority of virus shed in saliva is derived from an HLA class II-negative cell.

Synergistic activation of cells by Epstein-Barr virus and B-cell growth factor.

Infection with Epstein-Barr virus (EBV) is initiated by virus binding to the C3dg-C3d receptor CR2. Several workers have implicated this receptor in the control of B-cell activation by examining the effects of antibodies to CR2 and isolated C3d on B-cell proliferation and differentiation. We report here on the activating effects of irradiated EBV, which retains its capacity to bind to CR2 but loses its ability to function as a T-independent B-cell activator. EBV synergized with B-cell growth factor in the induction of uptake of tritiated thymidine by T cell-depleted leukocytes from seronegative donors but did not induce secretion of immunoglobulin. Synergism could be inhibited with an anti-viral antibody that inhibited binding of EBV to CR2. No similar synergism was found between EBV and recombinant interleukin 2, interleukin 1 alpha, or gamma interferon or with the lipid A fraction of bacterial lipopolysaccharide. EBV may thus initiate B-cell activation as it binds to CR2. Infectious virus may, under normal circumstances, induce the cell to make those growth factors necessary to support B-cell proliferation; the difficulty of transforming cells with transfected EBV DNA may in part reflect the absence of an activation event provided by intact virus as it attaches to CR2. The synergism of EBV and B-cell growth factor more clearly distinguishes the effects of B-cell growth factor from those of interleukin 1 and interleukin 2 in other models of B-cell activation. Thus, this may be a useful model for further delineation of unique effects of B-cell growth factor on B-cell function.

Epstein-Barr virus enters B cells and epithelial cells by different routes.

Epstein-Barr virus (EBV) infects two cell types, B lymphocytes and epithelial cells. Electron microscopic studies have shown that the virus fuses with the lymphoblastoid cell line Raji but is endocytosed into thin-walled non-clathrin-coated vesicles in normal B cells before fusion takes place. To compare early interactions of EBV with epithelial cells and B cells, a fluorescence dequenching assay of fusion was employed, using virus labeled either with the pH-insensitive probe octadecyl rhodamine B chloride (R18) or with 5(N-octadecanoyl) aminofluorescein (AF), which loses emission intensity at a pH below 7.4. Fusion of virus labeled with R18 could be monitored with B cells, Raji cells, and epithelial cells. Lowering the extracellular pH or pretreatment of cells with ammonium chloride or methylamine had no effect on these measurements. In contrast, fusion of virus labeled with AF could be measured with Raji cells and epithelial cells, but not with normal B cells unless cells were previously treated with ammonium chloride. Fusion of virus with normal B cells was inhibited with chlorpromazine, chloroquine, and sodium azide, but none of these reagents had any effect on fusion with Raji or epithelial cells. These results suggest that entry of EBV into nonpolarized suspensions of epithelial cells occurs by fusion at the cell surface, that EBV may be incapable of fusing with normal B cells unless it has first been endocytosed, and that pH appears to be irrelevant to either event. A combination of the two probes, R18 and AF, may have general use for determining the sites of entry of enveloped viruses that fuse in a pH-independent manner.

Epstein-Barr virus lacking glycoprotein gp42 can bind to B cells but is not able to infect.

The Epstein-Barr virus gH-gL complex includes a third glycoprotein, gp42, which is the product of the BZLF2 open reading frame (ORF). gp42 has been implicated as critical to infection of the B lymphocyte by virtue of its interaction with HLA class II on the B-cell surface. A neutralizing antibody that reacts with gp42 inhibits virus-cell fusion and blocks binding of gp42 to HLA class II; antibody to HLA class II can inhibit infection, and B cells that lack HLA class II can only be infected if HLA class II expression is restored. To confirm whether gp42 is an essential component of the virion, we derived a recombinant virus with a selectable marker inserted into the BZLF2 ORF to interrupt expression of the protein. A complex of gH and gL was expressed by the recombinant virus in the absence of gp42. Recombinant virus egressed from the cell normally and could bind to receptor-positive cells. It had, however, lost the ability to infect or transform B lymphocytes. Treatment with polyethylene glycol restored the infectivity of recombinant virus, confirming that gp42 is essential for penetration of the B-cell membrane.

Synthesis and processing of glycoprotein gG of herpes simplex virus type 2.

Monoclonal antibody 13 alpha C5-1-A11 immunoprecipitated two major polypeptides of molecular weights 108,000 and 120,000 from extracts of herpes simplex virus type 2-infected BHK-21 cells labeled with [35S]methionine or [3H]glucosamine. In pulse-chase experiments, both labels were chased from the 120,000-molecular-weight peptide (120K peptide) into the 108K molecule. Endoglycosidase H (endo H) reduced the 120K peptide to a 112K peptide but did not affect the 108K peptide. Similar profiles were obtained with monoclonal antibody AP-1 which reacts with a 92K glycoprotein, gG, which maps to the short unique region of the genome. Cross-absorption experiments indicated that both antibodies reacted with the same peptides, suggesting that the 120K peptide is a partially glycosylated high-mannose-type precursor of gG (pgG1). Immunoprecipitation from monensin-treated cells indicated that pgG1(120K) may undergo peptide cleavage to form a 74K high-mannose-type peptide (pgG2) and that this 74K peptide may be further processed into an endo H-resistant 110K to 116K peptide. In the presence of tunicamycin, gG(108K) was replaced by 110K and 105K peptides which were resistant to both endo H and endoglycosidase F. The 105K peptide was the only molecule labeled by [3H]galactose or [3H]glucosamine in the presence of tunicamycin, and none of the peptides were labeled with [3H]mannose, indicating the probable presence of O-linked sugars in the 105K peptide. Our results imply that cotranslational glycosylation of the unglycosylated precursor 110K peptide results in the high-mannose-type pgG1(120K), which probably undergoes peptide cleavage. This putative cleavage product may then mature into gG (108K) by the trimming of sugars and the addition of complex and probably O-linked sugars; the high-mannose-type pgG2(74K) is probably an intermediate peptide formed in this process.

A monoclonal antibody to glycoprotein gp85 inhibits fusion but not attachment of Epstein-Barr virus.

Epstein-Barr virus (EBV) codes for at least three glycoproteins, gp350, gp220, and gp85. The two largest glycoproteins are thought to be involved in the attachment of the virus to its receptor on B cells, but despite the fact that gp85 induces neutralizing antibody, no function has been attributed to it. As an indirect approach to understanding the role of gp85 in the initiation of infection, we determined the point at which a neutralizing, monoclonal antibody that reacted with the glycoprotein interfered with virus replication. The antibody had no effect on virus binding. To examine the effect of the antibody on later stages of infection, the fusion assay of Hoekstra and colleagues (D. Hoekstra, T. de Boer, K. Klappe, and J. Wilshaut, Biochemistry 23:5675-5681, 1984) was adapted for use with EBV. The virus was labeled with a fluorescent amphiphile that was self-quenched at the high concentration obtained in the virus membrane. When the virus and cell membrane fused, there was a measurable relief of self-quenching that could be monitored kinetically. Labeling had no effect on virus binding or infectivity. The assay could be used to monitor virus fusion with lymphoblastoid lines or normal B cells, and its validity was confirmed by the use of fixed cells and the Molt 4 cell line, which binds but does not internalize the virus. The monoclonal antibody to gp85 that neutralized virus infectivity, but not a second nonneutralizing antibody to the same molecule, inhibited the relief of self-quenching in a dose-dependent manner. This finding suggests that gp85 may play an active role in the fusion of EBV with B-cell membranes.

The Epstein-Barr virus-associated protein p105 is not encoded by the Epstein-Barr virus genome.

Rabbit antibodies made to an Epstein-Barr virus (EBV)-associated hydrophobic protein p105 that cross-reacts antigenically with the herpes simplex virus glycoprotein gB inhibited the ability of EBV to induce immunoglobulin synthesis by normal B cells. Sequencing of p105 indicated that it was a keratin-like protein and not encoded by EBV. Analysis of EBV-producing cells with and without mycoplasma indicated that p105 is probably a mycoplasma protein that associates with the EBV virion.

Modification of Epstein-Barr virus replication by tunicamycin.

The effect of tunicamycin, which inhibits N-linked glycosylation, on the replication of Epstein-Barr virus was examined. Tunicamycin markedly reduced the yield of virus from producing cells. At concentrations of 1 to 2 micrograms of tunicamycin per ml, there was a buildup of intracellular virus in P3HR1-Cl13 cells but not in MCUV5 cells; at a concentration of 5 micrograms of tunicamycin per ml in P3HR1-Cl13 cells, viral DNA synthesis was inhibited as well. Viral glycoproteins lacking N-linked sugars were apparently inserted into the cell membrane, and the small amount of virus made in the presence of drug was able to bind specifically to its receptor on B cells. However, the ability of the virus to induce immunoglobulin secretion by fresh human lymphocytes was impaired. This implies a role for viral glycoproteins in the penetration as well as the attachment of virus.

Detection by monoclonal antibodies of an early membrane protein induced by Epstein-Barr virus.

Two monoclonal antibodies, E8B3 and E8D2, were raised against Epstein-Barr virus (EBV)-producing cells and were shown to immunoprecipitate a protein with an approximate molecular weight of 105,000 (p105). The protein was detectable only in EBV-containing cells which were supporting the virus lytic cycle, and its synthesis increased after cells were induced with phorbol esters. The molecule was radiolabeled and immunoprecipitated from virus-producing cells that had been extrinsically labeled with 125I, and the antibodies E8B3 and E8D2 reacted in immunofluorescence assays with infected cells; the molecule was also associated with virion particles. Synthesis of p105 was not blocked by phosphonoacetic acid and could be induced in Raji cells by superinfection with virus derived from P3HR1 cells. These data support the conclusion that p105 is an EBV-specific early membrane protein.

The Epstein-Barr virus (EBV) BZLF2 gene product associates with the gH and gL homologs of EBV and carries an epitope critical to infection of B cells but not of epithelial cells.

Glycoprotein gp85, the product of the BXLF2 open reading frame (ORF), is the gH homolog of Epstein-Barr virus (EBV) and has been implicated in penetration of virus into B cells. Like its counterparts in other herpesviruses, it associates with a gL homolog, gp25, which is the product of the BKRF2 ORF. Unlike the gH homologs of other herpesviruses, however, gp85 also complexes with two additional glycoproteins of 42 and 38 kDa. Glycoproteins gp42 and gp38 were determined to be alternatively processed forms of the BZLF2 gene product. Coexpression of EBV gH and gL facilitated transport of gH to the cell surface and resulted in formation of a stable complex of gH and gL. It also restored expression of an epitope recognized by monoclonal antibody E1D1, which immunoprecipitates the native gH complex but not recombinant gH expressed in isolation. Coexpression of gH, gL, and the BZLF2 ORF restored expression of an epitope recognized by a second monoclonal antibody, F-2-1, which immunoprecipitates the native gH-gL-gp42/38 complex but not the complex of recombinant gH and gL alone. The epitope recognized by antibody F-2-1 was mapped to the BZLF2 gene product itself. Antibody F-2-1 inhibited the ability of EBV to infect B lymphocytes but had no effect on the ability of the virus to infect the epithelial cell line SVK-CR2. In contrast, antibody E1D1 had no effect on infection of the B-cell line but inhibited infection of the epithelial cell line. These results indicate that penetration of the two cell types by EBV involves differential use of the gH-gL-gp42/38 complex and suggest the hypothesis that the BZLF2 gene product has evolved as a unique adaptation to infection of B lymphocytes by EBV.

Characterization of envelope proteins of alcelaphine herpesvirus 1.

Alcelaphine herpesvirus 1 is a gammaherpesvirus which causes malignant catarrhal fever, an acute lymphoproliferative disorder of cattle and other susceptible Bovidae, which is almost invariably fatal. A preliminary analysis of proteins induced by the virus indicated that as many as six glycoproteins and one nonglycosylated molecule might be present in the virus envelope. Monoclonal antibodies selected for recognition of virion envelope proteins included two that recognized a complex of infected cell proteins, designated the gp115 complex, and neutralized virus infectivity in the absence of complement. The gp115 complex consisted of five glycoproteins of 115, 110, 105, 78, and 48 kilodaltons (kDa), and all except the 48-kDa species reacted with antibody in Western blots (immunoblots). Pulse-chase experiments analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing and nonreducing conditions suggested that the 110-kDa protein was the precursor molecule which was processed by addition of sugars to 115 kDa. The 115-kDa protein was cleaved to form a disulfide-linked heterodimer of 78 and 48 kDa, which was the mature form of the molecule incorporated into the virion envelope. The glycoprotein contained N-linked sugars, but little or no O-linked sugar was present. The relative abundance of the mature protein and its ability to induce neutralizing antibodies suggest that it will prove useful to studies aimed at elucidating the biology and pathogenesis of alcelaphine herpesvirus 1.