Production of rabbit antibodies against the viral capsid antigen (VCA) of the Epstein-Barr virus (EBV)

Neutralization of Epstein-Barr virus by nonimmune human serum. Role of cross-reacting antibody to herpes simplex virus and complement

These studies were carried out to investigate the mechanism of neutralization of purified Epstein-Barr virus (EBV) by fresh human serum from normal individuals lacking antibody to the EBV viral capsid (VCA) and nuclear antigens (EBNA). Such individuals thus lack serological evidence of immunity to EBV. Although an enzyme-linked immunosorbent assay (ELISA) with highly purified immobilized EBV detected low levels of IgG antibody reactive with EBV in these normal nonimmune sera, this antibody failed to neutralize EBV in the absence of complement. Studies with depleted sera and mixtures of purified complement proteins at physiologic concentrations showed that the IgG antibody and C1, C4, C2, and C3 of the classical pathway were able to fully neutralize EBV. Mixtures of the purified components of the alternative pathway at physiologic concentrations failed to neutralize purified EBV in the presence or absence of the antibody and the alternative pathway did not potentiate classical pathway-mediated neutralization. No evidence for a requirement for C8 was obtained, precluding lysis as the mechanism of neutralization. Since C3 deposition on the viral surface accompanied classical pathway activation, viral neutralization is most likely secondary to the accumulation of complement protein on the viral surface. A coating of protein on the virus could interfere with attachment to, or penetration of potentially susceptible cells. Experiments were undertaken to determine the specificity of the IgG antibody in the sera of EBV nonimmune individuals which, together with complement, neutralized EBV. Both purified EBV and herpes simplex I (HSV-1) absorbed the EBV ELISA reactivity and EBV-neutralizing activity of nonimmune sera, whereas another member of the herpesvirus group, cytomegalovirus, was inactive in this regard. HSV-1 was quantitatively more efficient than EBV in absorbing reactivity, a finding that indicates that the antibody has a higher affinity for HSV-1 than for EBV. Further absorption studies indicated that the cross-reaction occurred in both directions as EBV also absorbed HSV-1 reactive antibodies as tested in an HSV-1 ELISA. EBV was also less efficient than HSV-1 in absorbing reactivity with HSV-1. A serum lacking detectable antibodies to both EBV and HSV-1 failed to neutralize EBV. These studies cumulatively indicate that fresh serum from EBV nonimmune individuals neutralizes EBV by the combined action of a previously undescribed cross-reacting antibody apparently elicited by HSV-1 and C1, C4, C2, and C3 of the classical complement pathway.

Monoclonal antibody against a 250,000-dalton glycoprotein of Epstein-Barr virus identifies a membrane antigen and a neutralizing antigen

An antibody-secreting hybrid cell line was produced by fusion of mouse myeloma cells with splenocytes from mice immunized with virions of the B95-8 strain of Epstein-Barr Virus (EBV). The monoclonal IgG antibody was shown to have anti-EBV activity by the following criteria: (i) It reacted with the membranes and the cytoplasm of seven different EBV-producing lines, but with no nonproducing line. (ii) The individual cells identified by the murine antibody were shown to be the same cells identified by a human serum having anti-EBV activity. (iii) The antibody significantly reduced the infectivity of two independent strains of EBV (namely, P3HR1K and B95-8). The antigen being recognized was characterized by immunoprecipitations of radiolabeled EBV-producer cell lysates. A single glycoprotein with an estimated molecular weight of 250,000 was identified. It is concluded that neutralization of EBV can be achieved by an IgG-class monoclonal antibody directed against a single antigenic site on a 250,000-dalton glycoprotein, which is a constituent of the EBV virion.