Production of recombinant proteins by vaccinia virus in a microcarrier based mammalian cell perfusion bioreactor

The HeLa cell-vaccinia virus expression system was evaluated for the production of recombinant proteins (enhanced green fluorescent protein (EGFP) and HIV envelope coat protein, gp120) using microcarriers in 1.5 L perfused bioreactor cultures. Perfusion was achieved by use of an alternating tangential flow device (ATF), increasing the length of the exponential phase by 50 h compared to batch culture and increasing the maximum cell density from 1.5x10(6) to 4.4x10(6) cell/mL. A seed train expansion method using cells harvested from microcarrier culture and reseeding onto fresh carriers was developed. EGFP was first used as a model protein to study process parameters affecting protein yield, specifically dissolved oxygen (DO) and temperature during the production phase. The highest level of EGFP, 12+/-1.5 microg/10(6) infected cells, was obtained at 50% DO and 31 degrees C. These setpoints were then used to produce glycoprotein, gp120, which was purified and deglycosylated, revealing a significant amount of N-linked glycosylation. Also, biological activity was assayed, resulting in an ID50 of 3.1 microg/mL, which is comparable to previous reports.     

Alternate pathways of secretion of simian immunodeficiency virus envelope glycoproteins.

A biotinylation assay was used to detect the envelope glycoprotein of the simian immunodeficiency virus (SIV) envelope glycoprotein expressed by a recombinant vaccinia virus on the surface of HeLa T4 cells. The relationship between the detection of the envelope glycoprotein on the cell surface and its secretion from the cell was examined. It was found that much more gp120 was released into the culture medium than could be accounted for by shedding of the biotinylated SIV envelope protein from the cell surface. Treatment with the ionophore monensin showed that this drug did not block the secretion of gp120 into the culture medium even though the expression of gp120 on the cell surface was strongly downregulated. Similar results were observed for the secretion of gp120 in HUT78 cells infected with SIVmac251 virus. Brefeldin A, on the other hand, inhibited both the detection of gp120 on the cell surface and its secretion into the culture medium. On the basis of these results, we propose that gp120 can be secreted into the culture medium via at least two pathways. One pathway involves the dissociation of gp120 from membrane-associated gp41-gp120 complexes on the cell surface. However, the major pathway involves the secretion of gp120 without its transitory appearance on the cell surface as part of a gp41-gp120 complex.     

Use of a stationary bed reactor and serum-free medium for the production of recombinant proteins in insect cells.

Insect cells (Spodoptera frugiperda) have been cultured in a stationary bed reactor, packed with a fibrous polyester carrier. When the bioreactor was perfused with serum-supplemented medium, a cell density of 6 x 10(6) cells ml-1 packed carrier was reached. Scanning electron microscopy investigations have shown that the insect cells grew along the three-dimensionally oriented fibers of the Fibra-cel carrier. After infection of the logarithmically growing cells with a recombinant baculovirus (Autographa californica) containing the gene coding for beta-galactosidase, the medium in the bioreactor was changed to serum-free medium. At day 13 postinfection (p.i.), a beta-galactosidase level of 320 microgram ml-1 and, at day 17 p.i., a virus titer of 2.1 x 10(8) TCID50 units ml-1 (day 17 p.i.) were reached. In another bioreactor, operated in a similar way but with serum-containing medium, a beta-galactosidase concentration of 360 microgram ml-1 and a virus titer of 2.3 x 10(8) TCID50 units ml-1 were obtained. These results indicate the potential use of this production system for the production of recombinant protein and baculovirus in insect cells.     

Vaccinia virus-based expression of gp120 and EGFP: survey of mammalian host cell lines

Production of recombinant proteins with the vaccinia virus expression system in five mammalian cell lines (HeLa, BS-C-1, Vero, MRC-5, and 293) was investigated for protein yield and proper posttranslational modifications. Regulatory acceptance of the host cell line was taken into consideration, where Vero, MRC-5, and 293 were considered more acceptable to the regulatory authorities. Relevant process knowledge for ease of scale-up with the particular cell type was also considered. Two proteins were expressed, enhanced green fluorescent protein (EGFP) in the cytoplasm and gp120, an HIV envelope coat protein that is secreted into the culture medium. HeLa cells produced the most EGFP at 17.2 microg/well with BS-C-1 and 293 following. BS-C-1 produced the most gp120 at 28.2 microg/mL with 293 and Vero following. Therefore, of the three most appropriate cell lines (Vero, MRC-5, and 293) for production processes, the best results were obtained with 293 cells. Although MRC-5 had a very high productivity on a per cell basis, the low cell density and slow growth rate made the overall production insufficient. Because gp120 contained a significant amount of posttranslational modification, this protein, produced by the different cell lines, was further analyzed by PNGase digestion suggesting N-linked glycosylation modifications in all cell lines tested. On the basis of these results and overall process considerations, 293 cells are recommended for further production process optimization in a serum-free suspension system.     

Temporal expression of HIV-1 envelope proteins in baculovirus-infected insect cells: implications for glycosylation and CD4 binding

Three different human immunodeficiency virus type I (HIV-1) envelope derived recombinant proteins and the full length human CD4 polypeptide were expressed in Spodoptera frugiperda (Sf9) cells. DNA constructs encoding CD4, gp120, gp160, and gp160 delta (full length gp160 minus the transmembrane and cytoplasmic region of gp41) were cloned into the baculovirus expression vector pVL941 or a derivative and used to generate recombinant viruses in a cotransfection with DNA from Autographa californica nuclear polyhedrosis virus (AcMNPV). Western blotting of cell extracts of the recombinant HIV-1 proteins showed that for each construct two major bands specifically reacted with anti-HIV-1 envelope antiserum. These bands corresponded to glycosylated and nonglycosylated versions of the HIV proteins as determined by 3H-mannose labeling and tunicamycin treatment of infected cells. A time course of HIV envelope expression revealed that at early times post-infection (24 hours) the proteins were fully glycosylated and soluble in nonionic detergents. However, at later times postinfection (48 hours), expression levels of recombinant protein reached a maximum but most of the increase was due to a rise in the level of the nonglycosylated species, which was largely insoluble in nonionic detergents. Thus, it appears that Sf9 cells cannot process large amounts of glycosylated recombinant proteins efficiently. As a measure of biological activity, the CD4 binding ability of both glycosylated and nonglycosylated recombinant HIV envelope proteins was tested in a coimmunoprecipitation assay. The results showed that CD4 and the glycosylated versions of recombinant gp120 or gp160 delta specifically associated with one another in this analysis. Nonglycosylated gp120 or gp160 delta proteins from tunicamycin-treated cultures did immunoprecipitate with anti-HIV-1 antiserum but did not interact with CD4. We conclude that production of native HIV envelope proteins, as measured by addition of carbohydrate side chains and ability to bind CD4, peaks early after infection in baculovirus-infected insect cells.     

Production of recombinant protein using the HeLa S3-vaccinia virus expression system: bioreactor perfusion and effects of post-infection temperature

Adaptation of the vaccinia virus expression system to HeLa S3 suspension bioreactor culture for the production of recombinant protein was conducted. Evaluation of hollow fiber perfusion of suspension culture demonstrated its potential for increased cell density prior to infection. The hollow fiber was also used for medium manipulations prior to infection. Two process parameters, multiplicity of infection (MOI) and temperature during the protein production phase, were evaluated to determine their effect on expression of the reporter protein, enhanced green fluorescent protein (EGFP). An MOI of 1.0 was sufficient for infection and led to the highest level of intracellular EGFP expression. Reducing the temperature to 34 degrees C during the protein production phase increased production of the protein two-fold compared to 37 degrees C in spinner flask culture. Scaling up the process to a 1.5-liter bioreactor with hollow fiber perfusion led to an overall production level of 9.9 microg EGFP/10(6) infected cells, or 27 mg EGFP per liter.     

Construction and use of a human immunodeficiency virus vector for analysis of virus infectivity.

We constructed a recombinant human immunodeficiency virus (HIV) vector to facilitate studies of virus infectivity. A drug resistance gene was inserted into a gp160- HIV proviral genome such that it could be packaged into HIV virions. The HIV genome was rendered replication defective by deletion of sequences encoding gp160 and insertion of a gpt gene with a simian virus 40 promoter at the deletion site. Cotransfection of the envelope-deficient genome with a gp160 expression vector resulted in packaging of the defective HIV-gpt genome into infectious virions. The drug resistance gene was transmitted and expressed upon infection of susceptible cells, enabling their selection in mycophenolic acid. This system provides a quantitative measure of HIV infection, since each successful infection event leads to the growth of a drug-resistant colony. The HIV-gpt virus produced was tropic for CD4+ human cells and was blocked by soluble CD4. In the absence of gp160, noninfectious HIV particles were efficiently produced by cells transfected with the HIV-gpt genome. These particles packaged HIV genomic RNA and migrated to the same density as gp160-containing virions in a sucrose gradient. This demonstrates that HIV virion formation is not dependent on the presence of a viral envelope glycoprotein. Expression of a murine leukemia virus amphotropic envelope gene in cells transfected with HIV-gpt resulted in the production of virus capable of infecting both human and murine cells. These results indicate that HIV can incorporate envelope glycoproteins other than gp160 onto particles and that this can lead to altered host range. Like HIV type 1 and vesicular stomatitis virus(HIV) pseudotypes, gp-160+ HIV-gpt did not infect murine NIH 3T3 cells that bear human CD4, confirming that these cells are blocked at an early stage of HIV infection.     

Chimeric influenza virus induces neutralizing antibodies and cytotoxic T cells against human immunodeficiency virus type 1.

Expression vectors based on DNA or plus-stranded RNA viruses are being developed as vaccine carriers directed against various pathogens. Less is known about the use of negative-stranded RNA viruses, whose genomes have been refractory to direct genetic manipulation. Using a recently described reverse genetics method, we investigated whether influenza virus is able to present antigenic structures from other infectious agents. We engineered a chimeric influenza virus which expresses a 12-amino-acid peptide derived from the V3 loop of gp120 of human immunodeficiency virus type 1 (HIV-1) MN. This peptide was inserted into the loop of antigenic site B of the influenza A/WSN/33 virus hemagglutinin (HA). The resulting chimeric virus was recognized by specific anti-V3 peptide antibodies and a human anti-gp120 monoclonal antibody in both hemagglutination inhibition and neutralization assays. Mice immunized with the chimeric influenza virus produced anti-HIV antibodies which were able to bind to synthetic V3 peptide, to precipitate gp120, and to neutralize MN virus in human T-cell culture system. In addition, the chimeric virus was also capable of inducing cytotoxic T cells which specifically recognize the HIV sequence. These results suggest that influenza virus can be used as an expression vector for inducing both B- and T-cell-mediated immunity against other infectious agents.     

Inactivation of Bacteriophages by Thiol Reducing Agents

Adaptation of the vaccinia virus expression system to HeLa S3 suspension bioreactor culture for the production of recombinant protein was conducted. Evaluation of hollow fiber perfusion of suspension culture demonstrated its potential for increased cell density prior to infection. The hollow fiber was also used for medium manipulations prior to infection. Two process parameters, multiplicity of infection (MOI) and temperature during the protein production phase, were evaluated to determine their effect on expression of the reporter protein, enhanced green fluorescent protein (EGFP). An MOI of 1.0 was sufficient for infection and led to the highest level of intracellular EGFP expression. Reducing the temperature to 34 °C during the protein production phase increased production of the protein two-fold compared to 37 °C in spinner flask culture. Scaling up the process to a 1.5-liter bioreactor with hollow fiber perfusion led to an overall production level of 9.9 μg EGFP/10⁶ infected cells, or 27 mg EGFP per liter.     

Chemically induced infection of CD4-negative HeLa cells with HIV-1

Infection with human immunodeficiency virus type-1 (HIV-1) requires the presence of a CD4 molecule and chemokine receptors such as CXCR4 or CCR5 on the surface of target cells. However, it is still not clear how the virus enters the cells. Although CD4 was initially identified as the primary receptor for HIV-1, the expression of CD4 or one of the chemokine receptors alone is not sufficient to render susceptibility to infection with the virus. To ascertain whether or not adsorption of the virus needs charge-to-charge interaction between viral envelope and host cell membrane protein(s) and if binding alone promotes penetration of the virus into the cells, we have developed a chemically induced infection system targeting a CD4-negative and CXCR4-positive HeLa cell clone (N7 HeLa) which is usually not susceptible to infection with the LAI strain of HIV-1. Use of a poly-L-lysine (PLL)-coated culture plate to enhance the attachment of the virus to the cells made N7 HeLa cells infectable with HIV-1 at very low efficiency. PLL alone cannot fully substitute for the function of the CD4 molecule. However, trypsin-treated viruses, which have largely lost infectivity to CD4-positive MT-4 cells that are highly susceptible to HIV-1 infection, enhanced infectivity against N7 HeLa cells when the PLL-coated plate was used. These results provide evidence that infection with HIV-1 requires both high binding affinity between viruses and cells, and then needs a modification of the viral envelope such as cleavage of gp120/160 to enhance the infection, probably resulting in exposure of the hydrophobic fusion domain of gp41. HIV-1 infection of N7 HeLa cells was also enhanced by treatment with low pH, 12-O-tetradecanoylphorbol-13-acetate (TPA) and some factor(s) from the MT-4 cell culture supernatant. Not only tight viral adsorption with cleavage of the viral envelope but also some activated status of the cells may be required for sufficient HIV-1 infection in this artificial condition.     

Elicitation of neutralizing antibodies by intranasal administration of recombinant vesicular stomatitis virus expressing human immunodeficiency virus type 1 gp120

Recombinant viral vectors are useful tools for AIDS vaccine development. However, expression of HIV-1 envelope genes using viral vectors has not been successful in the induction of potent neutralizing antibodies in vivo. We took advantage of the strong immunogenicity of vesicular stomatitis virus (VSV)-based vector and expressed HIV-1 HXB2 gp120 gene in the recombinant VSV. Our results showed that HIV-1 gp120 protein expressed by the recombinant VSV retained the native conformation of the protein to some degree and was recognized by two well-characterized broad anti-HIV-1 neutralizing monoclonal antibodies b12, 2G12. We further showed that only one time intranasal immunization with the recombinant VSV led to production of anti-HIV-1 anti-sera in mice. In addition, we found that the anti-sera had the ability to neutralize not only HXB2 envelope-pseudotyped HIV-1 viruses but also HIV-1 pseudotyped viruses with JRFL envelopes. These results suggest that HIV-1 gp120 expressed by the recombinant VSV, in combination with the route of intranasal administration, is an effective strategy to evaluate the immunogenicity of HIV-1 envelope protein and its variants in mice.     

Recombinant gp120 specifically enhances tumor necrosis factor-alpha production and Ig secretion in B lymphocytes from HIV-infected individuals but not from seronegative donors

The effect of recombinant protein from the envelope (gp120) of the HIV on B lymphocytes purified from either HIV-infected individuals or healthy seronegative controls was examined. B cells from peripheral blood and lymph nodes of HIV-infected individuals spontaneously secreted TNF-alpha; this secretion was augmented by the presence of gp120, whereas B cells from healthy seronegative donors failed to secrete significant levels of TNF-alpha in the presence or absence of gp120. In a coculture system of B cells and chronically HIV-infected T cells (ACH-2), where viral expression is largely mediated by TNF-alpha, gp120 increased virus expression only if the B cells were obtained from HIV-infected individuals. The effects of gp120 on viral expression in this system were not mediated via CD4 receptor binding or FcR binding of anti gp120-gp120 immune complexes. Besides its effect on cytokine production, gp120 also stimulated Ig secretion in B cells from HIV-infected individuals, but not from normal donors. Finally, it was demonstrated by in situ hybridization that germinal centers of lymph nodes from HIV-infected individuals contain large amounts of HIV RNA that is in close proximity to germinal center B cells. These findings suggest that the hyperplastic germinal centers of lymph nodes provide an unique environment for virus expression and accumulation where gp120 stimulates B cells to secrete HIV inductive cytokines, such as IL-6 and TNF-alpha, and thereby further enhances virus expression in infected cells in a paracrine manner.     

A hybridoma-based in vitro translation system that efficiently synthesizes glycoproteins

Since a large number of eukaryotic proteins are glycoproteins, an efficient and easily available cell-free system for the production of recombinant glycoproteins is needed. We have successfully developed an efficient cell-free translation system derived from a monoclonal antibody-producing hybridoma for this purpose. While extracts from HeLa cells were very inefficient for production of an N-glycosylated form of human immunodeficiency virus type-1 envelope protein 120 (gp120), the hybridoma extract was able to fully N-glycosylate gp120. During cell-free translation, eIF2alpha and eIF2alpha-kinases in the hybridoma extracts were observed to become phosphorylated due to the presence of essential supplements creatine phosphate and ATP. Addition of recombinant GADD34 and/or K3L to the extract efficiently lowered the phosphorylation of eIF2alpha, and thereby increased protein synthesis. By using this improved system, biologically active human choriogonadotropin (hCG), a glycoprotein hormone consisting of alpha and beta subunits was successfully synthesized. In conclusion, the hybridoma extract supplemented with GADD34/K3L should become a useful tool to produce recombinant glycoproteins.     

A New Approach to Produce HIV-1 Envelope Trimers: BOTH CLEAVAGE AND PROPER GLYCOSYLATION ARE ESSENTIAL TO GENERATE AUTHENTIC TRIMERS*

The trimeric envelope spike of HIV-1 mediates virus entry into human cells. The exposed part of the trimer, gp140, consists of two noncovalently associated subunits, gp120 and gp41 ectodomain. A recombinant vaccine that mimics the native trimer might elicit entry-blocking antibodies and prevent virus infection. However, preparation of authentic HIV-1 trimers has been challenging. Recently, an affinity column containing the broadly neutralizing antibody 2G12 has been used to capture recombinant gp140 and prepare trimers from clade A BG505 that naturally produces stable trimers. However, this antibody-based approach may not be as effective for the diverse HIV-1 strains with different epitope signatures. Here, we report a new and simple approach to produce HIV-1 envelope trimers. The C terminus of gp140 was attached to Strep-tag II with a long linker separating the tag from the massive trimer base and glycan shield. This allowed capture of nearly homogeneous gp140 directly from the culture medium. Cleaved, uncleaved, and fully or partially glycosylated trimers from different clade viruses were produced. Extensive biochemical characterizations showed that cleavage of gp140 was not essential for trimerization, but it triggered a conformational change that channels trimers into correct glycosylation pathways, generating compact three-blade propeller-shaped trimers. Uncleaved trimers entered aberrant pathways, resulting in hyperglycosylation, nonspecific cross-linking, and conformational heterogeneity. Even the cleaved trimers showed microheterogeneity in gp41 glycosylation. These studies established a broadly applicable HIV-1 trimer production system as well as generating new insights into their assembly and maturation that collectively bear on the HIV-1 vaccine design.     

Biosynthesis and processing of human immunodeficiency virus type 1 envelope glycoproteins: effects of monensin on glycosylation and transport.

When human immunodeficiency virus type 1 envelope glycoproteins were expressed in 293 cells by using a recombinant adenovirus expression vector, the envelope precursor (gp160) was initially glycosylated by cotranslational addition of N-linked high-mannose oligosaccharide units to the protein backbone and then cleaved to gp120 and gp41. The subunits gp120 and gp41 were then further modified by the addition of fucose, galactose, and sialic acid, resulting in glycoproteins containing a mixture of hybrid and complex oligosaccharide side chains. A fraction of glycosylated gp160 that escaped cleavage was further modified by the terminal addition of fucose and galactose, but the addition of sialic acid did not occur, consistent with the notion that it is compartmentalized separately from the gp120 envelope protein. Processing and transport of gp160 were blocked by the monovalent ionophore monensin, which at high concentrations (25 microM and above) was a potent inhibitor of the endoproteolytic cleavage of gp160; at lower concentrations (1 to 10 microM), it selectively blocked the secondary glycosylation steps so that smaller products were produced. Monensin (1 microM) treatment also resulted in a reduction in syncytium formation, which was observed when recombinant infected cells were cocultivated with CD4-bearing HeLa cells. The infectivity of human immunodeficiency virus type 1 was also reduced by monensin treatment, a decrease that may be due to incompletely glycosylated forms of gp120 that have a lower affinity for the CD4 receptor.     

Transcomplementation of simian immunodeficiency virus Rev with human T-cell leukemia virus type I Rex.

A molecular clone of the simian immunodeficiency virus SIVSMM isolate PBj14, lacking the ATG initiation codon for Rev protein (PBj-1.5), did not produce virus or large unspliced or singly spliced viral RNA upon transfection of HeLa cells. Low but significant levels of virus and large viral RNA production were observed upon transfection of PBj-1.5 into HeLa Rev cells expressing the rev gene of human immunodeficiency virus type 1. Furthermore, abundant virus and large viral RNA production occurred upon transfection of PBj-1.5 into HeLa Rex cells expressing the rex gene of human T-cell leukemia virus type I. Virus produced from HeLa Rex and HeLa Rev transfections was infectious, produced large amounts of virus, and was cytopathic for Rex-producing MT-4 cells. In contrast, no or only low levels of virus production were observed upon infection of H9 cells. These studies show that a defective SIV rev gene can be transcomplemented with human immunodeficiency virus type 1 Rev and with high efficiency by human T-cell leukemia virus type I Rex, and they suggest that rev-defective viruses could serve as a source for production of a live attenuated SIV vaccine.     

Reduced yield of infectious pseudorabies virus and herpes simplex virus from cell lines producing viral glycoprotein gp50.

Pseudorabies virus (PRV) glycoprotein gp50 is the homolog of herpes simplex virus (HSV) glycoprotein D. Several cell lines that constitutively synthesize gp50 were constructed. Vero cells, HeLa cells, and pig kidney (MVPK) cells that produce gp50 all gave reduced yields of PRV and HSV progeny viruses when compared with the parent cell line or the same cell line transfected to produce a different protein. The reduction in virus yield was greatest at low multiplicities of infection. The Vero and HeLa cells that produce gp50 showed an even greater reduction in HSV yield than in PRV yield. This phenomenon may be an example in a herpesvirus of the interference observed in retroviruses or cross-protection in plant virus systems.     

Synthesis and processing of human immunodeficiency virus type 1 envelope proteins encoded by a recombinant human adenovirus.

A recombinant adenovirus was constructed by inserting the human immunodeficiency virus type 1 (HIV-1) envelope gene downstream from the early region 3 (E3) promoter of adenovirus type 5 (Ad5), replacing the coding sequences of E3. The recombinant virus replicated as efficiently as the parent virus in all cell lines tested. Human cells infected with the recombinant virus synthesized the HIV-1 envelope precursor gp160, which was efficiently processed to the envelope glycoproteins gp120 and gp41. A human T-lymphoblast line (Molt-4) infected with the recombinant virus expressed HIV-1 envelope glycoproteins on the cell surface, leading to syncytium formation. The envelope gene was expressed from the E3 promoter at early times after infection and at late times from the major late promoter. When cotton rats were infected with the recombinant virus, antibodies against the HIV-1 envelope glycoproteins could be expressed in an immunoreactive form by the recombinant adenovirus, further illustrating the usefulness of adenoviruses as expression vectors.     

A single injection of recombinant measles virus vaccines expressing human immunodeficiency virus (HIV) type 1 clade B envelope glycoproteins induces neutralizing antibodies and cellular immune responses to HIV

The anchored and secreted forms of the human immunodeficiency virus type 1 (HIV-1) 89.6 envelope glycoprotein, either complete or after deletion of the V3 loop, were expressed in a cloned attenuated measles virus (MV) vector. The recombinant viruses grew as efficiently as the parental virus and expressed high levels of the HIV protein. Expression was stable during serial passages. The immunogenicity of these recombinant vectors was tested in mice susceptible to MV and in macaques. High titers of antibodies to both MV and HIV-Env were obtained after a single injection in susceptible mice. These antibodies neutralized homologous SHIV89.6p virus, as well as several heterologous HIV-1 primary isolates. A gp160 mutant in which the V3 loop was deleted induced antibodies that neutralized heterologous viruses more efficiently than antibodies induced by the native envelope protein. A high level of CD8+ and CD4+ cells specific for HIV gp120 was also detected in MV-susceptible mice. Furthermore, recombinant MV was able to raise immune responses against HIV in mice and macaques with a preexisting anti-MV immunity. Therefore, recombinant MV vaccines inducing anti-HIV neutralizing antibodies and specific T lymphocytes responses deserve to be tested as a candidate AIDS vaccine.     

Recombinant vaccinia virus induces neutralising antibodies in rabbits against Epstein-Barr virus membrane antigen gp340.

The Epstein-Barr virus membrane antigen gene gp340 was isolated, inserted into several strains of vaccinia virus and expressed under the control of a vaccinia virus promoter. The EBV-derived protein which was produced by the recombinant vaccinia viruses was heavily glycosylated, readily labelled with threonine, could be detected at the surface of infected cells and had a mol. wt. of approximately 340 kd, all of which are properties of the authentic gp340. Polyclonal rabbit antisera against gp340 and an EBV-neutralising anti-gp340 monoclonal antibody both recognised cells infected with the recombinant vaccinia viruses. Moreover, rabbits vaccinated with one of the recombinants produced antibodies that recognised EBV-containing lymphoblastoid cells and neutralised EBV.