Cell surface expression of human cytomegalovirus (HCMV) gp55-116 (gB): use of HCMV-recombinant vaccinia virus-infected cells in analysis of the human neutralizing antibody response.

Cell surface expression of the human cytomegalovirus (HCMV) major envelope glycoprotein complex, gp55-116 (gB), was studied by using monoclonal antibodies and an HCMV gp55-116 (gB) recombinant vaccinia virus. HCMV-infected human fibroblasts and recombinant vaccinia virus-infected HeLa cells expresses three electrophoretically distinct proteins of Mr 170,000, 116,000, and 55,000 on their surface. These species have been previously identified within infected cells and purified virions. Two unique neutralizing epitopes were shown to be present on the cell surface gp55-116 (gB). Utilizing HeLa cells infected with the gp55-116 recombinant vaccinia virus as a specific immunosorbent, we have shown that approximately 40 to 70% of the total serum virus-neutralizing activity of a group of individuals with past HCMV infections was directed against this single envelope glycoprotein. The implications of this finding for vaccine development are discussed.     

Structural proteins of hog cholera virus expressed by vaccinia virus: further characterization and induction of protective immunity.

A cDNA fragment covering the genomic region that encodes the structural proteins of hog cholera virus (HCV) was inserted into the tk gene of vaccinia virus. Expression studies with vaccinia virus/HCV recombinants led to identification of HCV-specific proteins. The putative HCV core protein p23 was demonstrated for the first time by using an antiserum against a bacterial fusion protein. The glycoproteins expressed by vaccinia virus/HCV recombinant migrated on sodium dodecyl sulfate-gels identically to glycoproteins precipitated from HCV-infected cells. A disulfide-linked heterodimer between gp55 and gp33 previously detected in HCV-infected cells was also demonstrated after infection with the recombinant virus. The vaccinia virus system allowed us to identify, in addition to the heterodimer, a disulfide-linked homodimer of HCV gp55. The vaccinia virus/HCV recombinant that expressed all four structural proteins induced virus-neutralizing antibodies in mice and swine. After immunization of pigs with this recombinant virus, full protection against a lethal challenge with HCV was achieved. A construct that lacked most of the HCV gp55 gene failed to induce neutralizing antibodies but induced protective immunity.     

Expression in recombinant vaccinia virus of the equine herpesvirus 1 gene encoding glycoprotein gp13 and protection of immunized animals.

The equine herpesvirus 1 (EHV-1) gene encoding glycoprotein 13 (gp13) was cloned into the hemagglutinin (HA) locus of vaccinia virus (Copenhagen strain). Expression of the gp13 gene was driven by the early/late vaccinia virus H6 promoter. Metabolically radiolabeled polypeptides of approximately 47 and 44 kilodaltons and 90 kilodaltons (glycosylated form) were precipitated with both polyclonal and gp13-specific monoclonal antibodies. Presentation of gp13 on the cytoplasmic membrane of cells infected with the recombinant gp13 vaccinia virus was demonstrated by immunofluorescence of unfixed cells. Inoculation of the recombinant gp13 vaccinia virus into guinea pigs induced neutralizing antibodies to both EHV-1 and vaccinia virus. Hamsters vaccinated with the recombinant gp13 vaccinia virus survived a lethal challenge with the hamster-adapted Kentucky strain of EHV-1. These results indicate that expression in vaccinia virus vectors of EHV-1 gp13, the glycoprotein homolog of herpes simplex virus gC-1 and gC-2, pseudorabies virus gIII, and the varicella-zoster virus gpV may provide useful vaccine candidates for equine herpesvirus infections.     

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.     

Identification of the human cytomegalovirus glycoprotein B gene and induction of neutralizing antibodies via its expression in recombinant vaccinia virus.

A human cytomegalovirus (HCMV) glycoprotein gene with homology to glycoprotein B (gB) of herpes simplex virus and Epstein-Barr virus and gpII of varicella zoster virus has been identified by nucleotide sequencing. The gene has been expressed in recombinant vaccinia virus and the gene product recognized by monoclonal antibodies and human immune sera. Rabbits immunized with the recombinant vaccinia virus produced antibodies that immunoprecipitate gB from HCMV-infected cells and neutralize HCMV infectivity in vitro. These data demonstrate a role for this protein in future HCMV vaccines.     

Expression, processing, and assembly of foot-and-mouth disease virus capsid structures in heterologous systems: induction of a neutralizing antibody response in guinea pigs.

Plasmids containing the foot-and-mouth disease virus structural protein precursor (P1) and 3C protease genes or the P1 gene alone were expressed in Escherichia coli. A recombinant baculovirus containing the P1 gene was also generated and expressed in Spodoptera frugiperda cells. Expression of the P1 and 3C genes in E. coli resulted in efficient synthesis and processing of the structural protein precursor and assembly into 70S empty capsids. This material reacted with neutralizing monoclonal antibodies which recognize only conformational epitopes and elicited a significant neutralizing antibody response in vaccinated guinea pigs. Expression of the P1 gene in E. coli resulted in synthesis of an insoluble product, whereas in insect cells infected with the recombinant baculovirus a soluble product was synthesized. Both soluble and insoluble P1 reacted with a 12S-specific monoclonal antibody, but only soluble P1 elicited a neutralizing antibody response in guinea pigs.     

Preferential suppression of yellow head virus (YHV) envelope protein gp116 in shrimp that survive challenge with YHV

The DNA sequence that encodes the first 406 amino acid residues at the N-terminus of yellow head virus (YHV) protein gp116, namely N/2 gp116deltaTM, and the DNA sequence that encodes the next 392 amino acid residues at the C-terminus of gp116 (without the transmembrane region), namely C/2 gp116deltaTM, were cloned into pGEX-6P-1 plasmid and expressed in E. coli. Both recombinant proteins were expressed, purified by SDS-PAGE and used to immunize mice. The mouse anti-recombinant N/2 gp116 and C/2 gp116 antisera bound specifically to both the recombinant proteins and to natural gp116 protein in YHV-infected haemolymph as shown by Western blotting and in tissues as shown by immunohistochemistry. Immunohistochemical localization of YHV using anti-gp116 antiserum or monoclonal antibodies specific to gp116 (V3-2B), gp64 (Y18) and p20 (Y19) revealed similar immunoreactivity patterns for all these reagents in muscle and mandibular tissue in shrimp showing gross signs of yellow head disease. However, in gill, hepatopancreas, lymphoid organ and thoracic ganglion tissues from experimental YHV-infected shrimp (Penaeus vannamei and Palaemon serrifer) that did not show signs of disease, immunoreactivity to gp116 was reduced or absent while that for gp64 and p20 remained intense. Thus, some shrimp species were able to selectively inhibit the synthesis of gp116 in a manner that was associated with absence of gross signs of disease.     

Induction of protective immunity in animals vaccinated with recombinant vaccinia viruses that express PreM and E glycoproteins of Japanese encephalitis virus.

A cDNA clone representing the genome of structural proteins of Japanese encephalitis virus (JEV) was inserted into the thymidine kinase gene of vaccinia virus strains LC16mO and WR under the control of a strong early-late promoter for the vaccinia virus 7.5-kilodalton polypeptide. Indirect immunofluorescence and fluorescence-activated flow cytometric analysis revealed that the recombinant vaccinia viruses expressed JEV E protein on the membrane surface, as well as in the cytoplasm, of recombinant-infected cells. In addition, the E protein expressed from the JEV recombinants reacted to nine different characteristic monoclonal antibodies, some of which have hemagglutination-inhibiting and JEV-neutralizing activities. Radioimmunoprecipitation analysis demonstrated that two major proteins expressed in recombinant-infected cells were processed and glycosylated as the authentic PreM and E glycoproteins of JEV. Inoculation of rabbits with the infectious recombinant vaccinia virus resulted in rapid production of antiserum specific for the PreM and E glycoproteins of JEV. This antiserum had both hemagglutination-inhibiting and virus-neutralizing activities against JEV. Furthermore, mice vaccinated with the recombinant also produced JEV-neutralizing antibodies and were resistant to challenge with JEV.     

Analysis of three late varicella-zoster virus proteins, a 125,000-molecular-weight protein and gp1 and gp3

Two monoclonal antibodies were prepared against varicella-zoster virus proteins. One of the monoclonal antibodies (10.2) reacted only with the nuclei of infected cells and immunoprecipitated one nonglycosylated late viral protein (125,000 molecular weight). The other monoclonal antibody (19.1) with neutralizing activity, reacted with membrane antigens of infected cells and with the varicella-zoster virus envelope and immunoprecipitated two late major viral glycoproteins (gp1 and gp3). Synthesis of the 125,000-molecular-weight protein, gp1, and gp3 began at 20 to 22 h postinfection, 2 h after the peak of viral DNA synthesis, and continued until 29 h postinfection, when the first progeny virus appeared in infected cells. Pulse-chase experiments showed that during pulse-labeling, only gp1 was detected, whereas during the chase period, gp1 as well as gp3 was detected in infected cells. Under nonreducing conditions, gp3 migrated in sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a 130,000-molecular-weight protein as compared with the 62,000-molecular-weight species obtained when gels were resolved under reducing conditions. This finding indicates that gp3 is a dimer that is disulfide linked.     

三个HIV-1广谱中和表位与HBV S抗原融合表达可诱导小鼠特异性抗体应答

为了增强HIV-1交叉中和表位的免疫原性,本研究使用PCR克隆技术将HIV-1三个具有一定广谱中和活性的线性抗原表位ELDKWA(简称2F5)、NWFDIT(简称4E10)和GPGRAFY(简称447-52D)基因分别融合到HBV S基因的3味端,构建了分别表达这三种融合基因的天坛株重组痘苗病毒疫苗RVJ1175S-2F5、RVJ1175S-4E10和RVJ1175S-447-52D,使用这三种重组痘苗病毒感染的细胞培养上清液经分离纯化制备了三种相应的蛋白亚单位疫苗PS-2F5、PS-4E10和PS-447-52D,对重组痘苗病毒和亚单位疫苗中三种融合抗原的生物学及免疫学特性进行了比较研究.PCR和测序结果表明,三种融合基因序列正确重组到痘苗病毒TK区,HBsAg的ELISA检测表明三种融合蛋白有效表达并分泌到细胞培养上清液中,SDS-PAGE凝胶电泳显示三种纯化后的融合蛋白均含分子量为23kD和27kD两种典型HBsAg条带,Western blot证明这两个条带均能与HBsAg抗体反应,并分别能与三种表位相应的HIV-1单抗2F5、4E10和447-52D反应.小鼠免疫结果显示,三种重组痘苗病毒疫苗和三种蛋白亚单位疫苗均能诱发较高水平的HBsAg抗体和相应HIV-1交叉中和表位抗体,蛋白亚单位疫苗诱生的这两类抗体均明显高于对应的重组痘苗病毒疫苗.这些结果为进一步研究三种表位抗体的中和活性和通过不同类型疫苗联合免疫进一步增强其免疫效果研究奠定了基础.     

Distribution of linear antigenic sites on glycoprotein gp55 of human cytomegalovirus.

Human convalescent serum and bacterial fusion proteins constructed from overlapping open reading frames of the nucleotide sequence encoding the human cytomegalovirus gp55 component of the major envelope glycoprotein complex, gp55-116 (gB), were used to localize antigenic regions recognized by human antibodies. All donor serum analyzed contained antibody reactivity for an antigenic site(s) located between amino acids (AA) 589 and 645, a region containing a previously defined linear site recognized by neutralizing monoclonal antibodies (U. Utz, B. Britt, L. Vugler, and M. Mach, J. Virol. 63:1995-2001, 1989). Furthermore, in-frame insertion of two different synthetic oligonucleotides encoding four amino acids into the sequence at nucleotide 1847 (AA 616) eliminated antibody recognition of the fusion protein. A second antibody binding site was located within the carboxyl terminus of the protein (AA 703 through 906). A competitive binding inhibition assay in which monoclonal antibodies were used to inhibit human antibody reactivity with recombinant gp55-116 (gB) suggested that the majority of human anti-gp55-116 (gB) antibodies were directed against a single antigenic region located between AA 589 and 645. Furthermore, inoculation of mice with fusion proteins containing this antigenic site led to a boostable antibody response. These results indicated that the antigenic site(s) located between AA 589 and 645 was an immunodominant antibody recognition site on gp55 and likely the whole gp55-116 (gB) molecule. The enhanced immunogenicity of this region in vivo may account for its immunodominance.     

Structural and functional properties of the 14-kDa envelope protein of vaccinia virus synthesized in Escherichia coli

Vaccinia virus is a highly cytocidal virus, but the steps that lead to virus penetration into cells, the first event in virus pathogenesis, have not been elucidated. We have shown that a 14-kDa envelope protein of vaccinia virus might play a major role in virus-penetration acting at the level of cell fusion (Rodriguez, J. F., Paez, E., and Esteban, M. (1987) J. Virol. 61, 395-404; Gong, S., Lai, C., and Esteban, M. (1990) Virology 178, 81-91). To carry out structural and functional studies on the vaccinia 14-kDa protein, it would be desirable to have a high level expression system, since the amount of protein that can be obtained from purified virus or from infected cells is very limited. In this investigation we demonstrate that the 14-kDa envelope protein of vaccinia virus is expressed in Escherichia coli in soluble form and at high levels. We establish, by several criteria, that the 14-kDa vaccinia virus protein expressed in E. coli is similar to the protein found in the virus particle based on apparent molecular mass, occurrence of disulfide-linked oligomers, reactivity against specific monoclonal antibody, and identity in amino-terminal sequence with the predicted DNA sequence of the gene. We define several structural and functional properties concerning the 14-kDa envelope protein of vaccinia virus. 1) 14 kDa is a trimer of identical subunits. 2) A monomer binds to itself more strongly than to a dimer or a trimer. 3) Oligomerization does not require cellular factors. 4) Trimers induce high titer neutralizing antibodies in animals which correlate with overall immunogenicity. 5) 14-kDa binds with specificity to the cell surface of cultured cells.     

Role of Immune Responses against the Envelope and the Core Antigens of Simian Immunodeficiency Virus SIVmne in Protection against Homologous Cloned and Uncloned Virus Challenge in Macaques

We previously showed that envelope (gp160)-based vaccines, used in a live recombinant virus priming and subunit protein boosting regimen, protected macaques against intravenous and intrarectal challenges with the homologous simian immunodeficiency virus SIVmne clone E11S. However, the breadth of protection appears to be limited, since the vaccines were only partially effective against intravenous challenge by the uncloned SIVmne. To examine factors that could affect the breadth and the efficacy of this immunization approach, we studied (i) the effect of priming by recombinant vaccinia virus; (ii) the role of surface antigen gp130; and (iii) the role of core antigens (Gag and Pol) in eliciting protective immunity. Results indicate that (i) priming with recombinant vaccinia virus was more effective than subunit antigen in eliciting protective responses; (ii) while both gp130 and gp160 elicited similar levels of SIV-specific antibodies, gp130 was not as effective as gp160 in protection, indicating a possible role for the transmembrane protein in presenting functionally important epitopes; and (iii) although animals immunized with core antigens failed to generate any neutralizing antibody and were infected upon challenge, their virus load was 50- to 100-fold lower than that of the controls, suggesting the importance of cellular immunity or other core-specific immune responses in controlling acute infection. Complete protection against intravenous infection by the pathogenic uncloned SIVmne was achieved by immunization with both the envelope and the core antigens. These results indicate that immune responses to both antigens may contribute to protection and thus argue for the inclusion of multiple antigens in recombinant vaccine designs.     

Identification and expression of a human cytomegalovirus glycoprotein with homology to the Epstein-Barr virus BXLF2 product, varicella-zoster virus gpIII, and herpes simplex virus type 1 glycoprotein H.

An open reading frame with the characteristics of a glycoprotein-coding sequence was identified by nucleotide sequencing of human cytomegalovirus (HCMV) genomic DNA. The predicted amino acid sequence was homologous with glycoprotein H of herpes simplex virus type 1 and the homologous protein of Epstein-Barr virus (BXLF2 gene product) and varicella-zoster virus (gpIII). Recombinant vaccinia viruses that expressed this gene were constructed. A glycoprotein of approximately 86 kilodaltons was immunoprecipitated from cells infected with the recombinant viruses and from HCMV-infected cells with a monoclonal antibody that efficiently neutralized HCMV infectivity. In HCMV-infected MRC5 cells, this glycoprotein was present on nuclear and cytoplasmic membranes, but in recombinant vaccinia virus-infected cells it accumulated predominantly on the nuclear membrane.     

Neutralizing antibodies in Borna disease virus-infected rats.

Borna disease is a neurologic syndrome caused by infection with a nonsegmented, negative-strand RNA virus, Borna disease virus. Infected animals have antibodies to two soluble viral proteins, p40 and p23, and a membrane-associated viral glycoprotein, gp18. We examined the time course for the development of neutralization activity and the expression of antibodies to individual viral proteins in sera of infected rats. The appearance of neutralizing activity correlated with the development of immunoreactivity to gp18, but not p40 or p23. Monospecific and monoclonal antibodies to native gp18 and recombinant nonglycosylated gp18 were also found to have neutralizing activity and to immunoprecipitate viral particles or subparticles. These findings suggest that gp18 is likely to be present on the surface of the viral particles and is likely to contain epitopes important for virus neutralization.     

Synthesis and processing of the envelope gp55-116 complex of human cytomegalovirus.

The envelope of human cytomegalovirus has been reported to contain between three and eight glycoproteins. Major constituents of the envelope include two abundant glycoproteins with estimated molecular weights of 55,000 (gp55) and 116,000 (gp116). These two glycoproteins have been shown to exist as a disulfide-linked complex (gp55-116) within the envelope of mature virions. Utilizing a panel of monoclonal antibodies reactive with the gp55-116 complex, we characterized the synthesis and processing of these two virion proteins. Infected cells were shown to contain two glycosylated proteins of 160,000 and 150,000 daltons as well as the mature gp55 and gp116. Pulse-chase analysis indicated that gp150 was a precursor protein of gp160. The mature gp55 and gp116 were generated, in turn, by cleavage of gp160. Antigenic and structural analysis revealed that gp55 and gp116 shared little structural homology and no detectable antigenic cross-reactivity. The results of this study are discussed in relation to the synthesis of envelope proteins of other herpesviruses.     

Fusion proteins encoded by orf 129L of ectromelia and orf A30L of smallpox viruses cross-react with neutralizing monoclonal antibodies

Open reading frame (orf) 129L of ectromelia (EV) and orf A30L of smallpox viruses (SPV) encoding fusion proteins were cloned and expressed in E. coli cells. The recombinant polypeptides (prA30L H pr129L) were purified from cell lysates by Ni-NTA chromatography. Recombinant polypeptides were able to form trimers in buffered saline and they destroyed under treatment with SDS and 2-mercaptoethanol. Reactivity of prA30L, pr129L and orthopoxvirus proteins was analyzed by ELISA and Western blotting with panel of 22 monoclonal antibodies (MAbs) against orthopoxviruses (19 against EV, 2 MAbs against vaccinia virus and 1 Mabs against cowpox virus). This data allowed us to conclude that there are 12 EV-specific epitopes of pr129L and EV fusion proteins, ten orthopox-specific epitopes of EV, VV, CPV fusion proteins, from them 9 orthopox-specific epitopes of prA30L and SPV fusion proteins. Five Mabs, which cross-reacted with orthopox-specific epitopes, were able to neutralize the VV on Vero cells and from them two MAbs has neutralizing activity against smallpox virus. Our findings demonstrate that 129L fusion protein have EV-specific epitopes, that EV 129L and SPV A30L fusion proteins have a several orthopox-specific epitopes to induce a neutralizing antibodies against human pathogenic orthopoxviruses.     

A cell surface protein that binds avian hepatitis B virus particles.

We have identified a 180-kDa cellular glycoprotein (gp180) that binds with high affinity to duck hepatitis B virus (DHBV) particles. The protein was detected by coprecipitating labeled duck hepatocyte proteins with virions or recombinant DHBV envelope proteins, using nonneutralizing monoclonal antibodies to the virion envelope. Binding of gp180 requires only the pre-S region of the viral large envelope protein, since recombinant fusion proteins bearing only this region efficiently coprecipitate gp180. The DHBV-gp180 interaction is blocked by two independent neutralizing monoclonal antibodies. The protein is found on both internal and surface membranes of the cell, and the species distribution of gp180 binding activity mirrors the known host range of DHBV infection. Functional gp180 is expressed in a wide variety of tissues in susceptible ducks.     

Characterization and expression of a glycoprotein encoded by the Epstein-Barr virus BamHI I fragment.

Computer-assisted analysis of the Epstein-Barr virus (EBV) open reading frame BILF2 (B95-8 nucleotides 150,525 to 149,782) predicts that it codes for a membrane-bound glycoprotein. [3H]glucosamine labeling of cells infected with vaccinia virus recombinants that expressed the BILF2 open reading frame revealed several diffuse species of glycoproteins of around 80,000 and 55,000 daltons. A monoclonal antibody derived from spleens of mice immunized with EBV immunoprecipitated the EBV-derived protein made by the vaccinia virus recombinants and also precipitated a late envelope glycoprotein with a mobility of 78,000 to 55,000 from EBV-producing cells. N-Glycanase treatment of the immunoprecipitated BILF2 product from EBV-producing cells resulted in a polypeptide of 28 kilodaltons, closely agreeing with the predicted molecular mass for the unmodified BILF2 gene product. Western (immuno-) blots using recombinant infected cells as a source of antigen showed that the majority of EBV-seropositive individuals have a serum antibody response to the BILF2-encoded gp78/55.