Production of infectious Epstein--Barr virus in mouse lymphocytes

Epithelial cell polarization is a determinant in the infectious outcome of immunoglobulin A-mediated entry by Epstein-Barr virus

Diseases of the nasopharyngeal epithelium due to Epstein-Barr virus (EBV) infection typically occur in chronic virus carriers with preexisting virus-specific antibodies. In vitro studies have shown that EBV-specific immunoglobulin A (IgA) promotes infection of human epithelial cells, otherwise refractory to EBV, via the polymeric immunoglobulin receptor (pIgR). To determine if EBV similarly exploits IgA transport mechanisms in vivo, we examined the fate of IgA-EBV complexes in the blood of mice, where pIgR-mediated transcytosis of IgA immune complexes through hepatocytes eliminates exogenous antigens from the circulation. By PCR analysis we showed hepatobiliary transport of IgA-EBV in viremic mice, but without detectable hepatocellular infection by immunostaining. Because efficient transport of EBV immune complexes might avert an infectious outcome, we modulated the transcytotic pathway in polarized Madin-Darby canine kidney (MDCK) cells transfected with pIgR to determine the effect on viral antigen expression. Like hepatocytes in vivo, MDCK cells in polarized monolayers translocated IgA-EBV from the basal cell face into apical medium without evidence for infection. However, when exposed to IgA-EBV as unpolarized single-cell suspensions, MDCK cells expressed EBV immediate-early and early antigens. These results suggest that pIgR-mediated transcytosis of pIgA-EBV through epithelium facilitates endogenous spread of EBV in long-term virus carriers, with infection being confined to cells with altered polarity from prior cytopathology.

Immortalization of human T lymphocytes after transfection of Epstein-Barr virus DNA

Epstein-Barr virus (EBV), a ubiquitous human herpesvirus, has the ability to transform human B lymphocytes. No other cell type has been experimentally transformed by EBV, either by intact virions or naked viral DNA and subgenomic fragments. Two immortalized human T-lymphoblastoid cell lines have now been established by transfecting cord blood lymphocytes with purified B95-8 viral DNA enclosed in fusogenic Sendai virus envelopes (RSVE) and then exposing the cells to EBV from a P3HR-1 cell subclone. One of these lines, which has been fully characterized, is termed HBD-1. This line is positive for EBV DNA and expresses surface OKT11, OKT4, and Tac receptors, but not M-1, mu immunoglobulin chains, EBV receptors, or B-1 surface markers. The cells contain fully rearranged T-cell receptor genes and germline immunoglobulin genes. The karyotype of the cells is normal, they do not require interleukin-2 for growth, and do not contain human T-lymphotropic virus type I. However, the HBD-1 cells contain incomplete EBV genomes and express several EBV-determined antigens, including the early antigen type D, membrane antigens, but not EBV-determined nuclear antigen (EBNA). This association of the EBV genome with permanently growing hematopoietic cells of non B-cell lineage should prove useful in studies on the mechanism of EBV-mediated cell transformation.

Infection of human epithelial cells by Epstein-Barr virus (EBV). II. Biochemical characterization of EBV-determined proteins synthesized in epithelial cells

Primary cultures of epithelial cells were grown from tonsils of patients with diseases not related to EBV. The cells were implanted with EBV receptors and exposed to EBV of the transforming (B95-8, AG-876) and nontransforming (P3HR-1) strains. The EBV-infected and control cells were pulsed with [35S]methionine at 18-24 h after infection, and cell extracts were prepared for immunoprecipitation with anti-EBV sera and analysis by gel electrophoresis and autoradiography. About 20 EBV-determined proteins ranging from 22 to 185 kDa were detected in P3HR-1 virus-infected epithelial cells. Only a few polypeptides were detected in extracts of cells infected with AG-876 virus while no EBV-specific proteins were immunoprecipitated from extracts of B95-8 virus-infected cells. These results demonstrate that the system of EBV receptor-implanted normal human epithelial cells can be used for direct biochemical analysis of EBV infection in the epithelial tissue.

Expression of a second Epstein-Barr virus-determined nuclear antigen in mouse cells after gene transfer with a cloned fragment of the viral genome

Large Epstein-Barr virus (EBV) DNA restriction fragments corresponding to regions transcribed in transformed, proliferating cells were cloned in a cosmid derivative of the dominant-acting selection vector pSV2-gpt. Recombinant vectors carrying the EcoRI A fragment of EBV DNA were modified in the region corresponding to the deletion of the virion DNA in the non-transforming viral substrain P3HR-1, to create a series of recombinants lacking parts of this region. The recombinant vectors were introduced into 3T3 mouse fibroblasts under selective conditions, and resistant clones shown to contain EBV DNA sequences were analyzed for the expression of EBV-related antigens detectable by direct, indirect, and anticomplement immunofluorescence techniques. Cells that contained the BamHI K fragment expressed the EBV-determined nuclear antigen (EBNA) as expected. Cells transfected with recombinant vectors containing the BamHI W, Y, and H fragment part of the EcoRI A fragment also express a nuclear antigen detectable with certain anti-EBNA-positive human sera in anticomplement immunofluorescence tests. The BamHI WYH-induced EBNA polypeptide is similar in size to the EBNA2 polypeptide in Raji cells, as shown by gel electrophoresis and immunoblotting. The antigen is not detected in cells transfected with EcoRI A-derived vectors in which the BamHI H fragment has been deleted or in cells transformed with vectors carrying the BamHI H fragment alone. Direct and indirect immunofluorescence did not reveal the presence of antigens associated with productive infection in any of the EBV DNA-transfected fibroblast clones.

Benign and malignant disease caused by EBV

Epstein-Barr virus (EBV) causes infectious mononucleosis as a primary disease. The virus infects more than 90% of the average population and persists lifelong in peripheral B-lymphocytes. The virus is produced in the parotid gland and spread via the oral route. Serology suggests that the Epstein-Barr virus might be involved in the causation of two neoplastic diseases of humans: African Burkitt's lymphoma and nasopharyngeal carcinoma. Whereas the development of the lymphoma has an even better linkage with chromosomal rearrangements, nasopharyngeal carcinoma shows a unique association with Epstein-Barr virus. Environmental factors, including traditional Chinese medicine, may be responsible for the enhanced risk of nasopharyngeal carcinoma in certain, predominantly Chinese, populations of southern Asia. Possible mechanisms leading to the establishment of the neoplastic manifestations will be discussed.

Infection of mouse lymphocytes by Epstein-Barr virus. II. Stimulation of cellular DNA synthesis by EBV in the absence of EBNA induction and cell transformation

Epstein-Barr virus (EBV) of the transforming and nontransforming strains induced transient stimulation of cellular DNA synthesis during lytic infection of normal mouse lymphocytes. In contrast to human B lymphocytes, the action of both EBV strains in mouse cells was additive. The nontransforming P3HR-1 virus had no cytotoxic effect on mouse lymphocytes. The EBV-infected, stimulated mouse lymphocytes did not express EB virus-determined nuclear antigen and do not grow into immortalized cell lines. The cells expressed EBV-determined early and virus capsid antigens. These results suggest that the stimulation of cellular DNA synthesis by EBV is independent of EBNA synthesis and cell transformation.

Pattern of Epstein-Barr virus (EBV)-specific proteins synthesized during primary lytic infection of mouse lymphocytes by EBV

Normal mouse lymphocytes were implanted with EBV receptors and exposed to the virus of P3HR-1 strain. 5% of the cells expressed early (EA) and viral capsid (VCA) antigens as assayed by immunofluorescence 24 h after the infection. Only 0.1% of cells expressed nuclear-like antigen (EBNA) 48 h post-infection. When labelled metabolically with [35S]methionine, extracted, immunoprecipitated with EBV-positive sera, and analyzed by SDS-gel electrophoresis and autoradiography, about 20 EBV-determined proteins ranging from 19 to 165 kd were detected. Their pattern and relative quantitative expression differed from those in P3HR-1 virus superinfected Raji cells. Polypeptides of approximate molecular size 78, 72, 65, 48 and 26.5 kd were predominant in EBV-infected mouse lymphocytes. In contrast, 130, 98, 59, 50.5 and 36 kd proteins were predominant in the induced Raji cells. Our results demonstrate that rodent lymphocytes can be used for the direct biochemical analysis of EBV-translational products during primary lytic infection in normal cells.

Infection of normal human epithelial cells by Epstein-Barr virus

Primary cultures of epithelial cells were grown from the tonsils and adenoids of patients with diseases not related to Epstein-Barr virus. The cells could not be infected by Epstein-Barr virus. Fluorescein-labeled Epstein-Barr virus and a cytofluorograph were then used to show that the epithelial cells do not have detectable receptors for the virus. However, implantation with Epstein-Barr virus receptors gave the cells the ability to bind the labeled virus. One to 5 percent of receptor-implanted cells exposed to the transforming B95-8 substrain of the virus expressed Epstein-Barr nuclear antigen. The early and viral capsid Epstein-Barr virus-determined antigens were not detected in the virus-infected cultures. The results show that normal human epithelial cells from the nasopharynx become susceptible to infection by Epstein-Barr virus when the membrane barrier resulting from the lack of viral receptors is overcome by receptor implantation.

Rescue of transforming Epstein-Barr virus (EBV) from EBV-genome-positive epithelial hybrid cells transfected with subgenomic fragments of EBV DNA

Transfection experiments using subgenomic fragments of the B95-8 strain of Epstein-Barr virus (EBV) DNA and EBV genome (HR-1)-positive epithelial/Burkitt hybrid cells (D98/HR-1) were carried out to determine whether an interaction between the transfecting virus fragment(s) and the endogenous HR-1 EBV genome could take place. Expression of EBV-specific antigens, including early antigen and virus capsid antigen, was examined in transfected cells by immunofluorescence. Attempts were also made to recover biologically active EBV from the D98/HR-1 cells after transfection with cloned fragments of B95-8 DNA. We found that D98/HR-1 cells transfected with the BamHI H or H, F, and X fragments were positive for early antigen 3 days after transfection. Spent media from transfected D98/HR-1 cells maintained for 20-30 days in culture were pooled, filtered, concentrated, and used as a potential source of virus to inoculate human umbilical cord blood lymphocytes. No evidence of transformation was observed with such preparations. However, if spent medium from D98/HR-1 cell cultures was first treated with iododeoxyuridine (to induce EBV DNA synthesis and replicative cycle) and then transfected with the BamHI H, F, and X fragments of B95-8 DNA and used to infect cord blood lymphocytes, transformation was obtained. A lymphoblastoid cell line derived in this manner, designated HI-HFX, is an EBV nuclear antigen-positive nonproducer cell line. Similar results were obtained with preparations from iododeoxyuridine-treated D98/HR-1 cells transfected with the EB 26-36 fragment of B95-8 DNA cloned in a Charon 4A vector. The EB 26-36 fragment contains the BamHI H, F, and X regions.

Limiting dilution analysis of Epstein-Barr virus-induced immunoglobulin production by human B cells

The Epstein-Barr virus (EBV) is a herpes virus that has the capacity to infect human B cells and to induce them to secrete immunoglobulin (Ig). In the current experiments, Poisson analysis of limiting dilution cultures has been used to study the activation of human peripheral B cells by the B95-8 strain of EBV. Under the culture conditions used, 0.2-1% of peripheral blood B cells were activated by EBV to secrete IgM or IgG. In addition, when multiple replicate cultures containing limited numbers of B cells were tested for IgM and for IgG production, the precursors for IgM and IgG segregated independently; thus, individual B cell precursors matured into cells secreting IgM or IgG but not both classes of Ig. Additional experiments using limiting dilutions of EBV were undertaken to study the viral requirements for B cell activation. These studies indicated that B cell activation by EBV to produce Ig was consistent with a "one-hit" model and inconsistent with a "two-hit" model. Taken together, these results indicate that infection by one EBV virion is sufficient to induce a precursor peripheral blood B cell to secrete Ig and that only one isotype of Ig is then secreted.

Migration inhibition caused by EBV-specific 48K subcomponent of EBNA and the associated 53K cellular protein

Leukocytes from EBV-seropositive but not seronegative healthy donors responded with significant migration inhibition to the 48K subcomponent of the Epstein-Barr virus determined nuclear antigen (EBNA), known to carry the virally determined antigenic specificity. A concentration of 10 micrograms/ml was still effective while 5 micrograms/ml had no detectable effect. EBNA-associated cellular 53K protein had no effect by itself, but it potentiated the effect of 48K, even if the latter was added at the subliminal concentration of 5 micrograms/ml. The related 53K protein, isolated from EBV-negative human lymphoma cells, was also effective, whereas the corresponding murine-tumor-associated 53K had no potentiating effect. Immunization of mice with an extract of DNA-binding proteins from EBV-carrying Raji cells, known to contain both 48K and 53K, induced a significant macrophage migration inhibition response, to both human 48K and 53K. Murine 53K was ineffective, however. Human but not murine 53K increased the migration inhibitory activity of subliminal concentrations of 48K in the murine macrophage system as well. These findings suggest that human but not murine 53K may reconstitute with 48K (EBNA) to form a highly immunogenic complex.

A microassay for quantitatively detecting the Epstein-Barr virus receptor on single cells utilizing flow cytometry

A quantitative microassay for detecting and analyzing the Epstein-Barr virus receptor (EBVR) utilizing fluorescein-conjugated virions is presented. The test is virus substrain-specific. Both the B95-8 and P3HR-1 strains were labelled and adsorbed to a variety of targets. Relative binding of virus was assessed by flow cytometry, the results being directly comparable with those obtained by earlier methods. Cell size and cellular DNA content were measured simultaneously with virus binding, thus enabling us to calculate EBVR density and to correlate receptor synthesis and cell cycle stage.