Clement A. Meseda

Smallpox Vaccine Does Not Protect Macaques with AIDS from a Lethal Monkeypox Virus Challenge

It is unknown whether smallpox vaccination would protect human immunodeficiency virus type 1 (HIV-1)-infected individuals, because helper CD4(+) cells, the targets of HIV-1 infection, are necessary for the induction of both adaptive CD8(+) cell and B cell responses. We have addressed this question in macaques and have demonstrated that, although smallpox vaccination is safe in immunodeficient macaques when it is preceded by immunization with highly attenuated vaccinia strains, the macaques were not protected against lethal monkeypox virus challenge if their CD4(+) cell count was <300 cells/mm(3). The lack of protection appeared to be associated with a defect in vaccinia-specific immunoglobulin (Ig) switching from IgM to IgG. Thus, vaccination strategies that bypass CD4(+) cell help are needed to elicit IgG antibodies with high affinity and adequate tissue distribution and to restore protection against smallpox in severely immunocompromised individuals.

Prime-boost immunization with DNA and modified vaccinia virus Ankara vectors expressing herpes simplex virus-2 glycoprotein D elicits greater specific antibody and cytokine responses than DNA vaccine alone

Several reports have indicated that prime-boost strategies of vaccination can enhance the level of specific immunity induced by nucleic acid vaccines. The present report describes such a strategy with herpes simplex virus (HSV)-2 glycoprotein D (gD), using combinations of plasmid vector that expresses gD (pgD2) and a recombinant modified vaccinia virus Ankara vector that expresses gD (MVA-gD2). The IgG antibody response to gD and the HSV-2 neutralizing antibody response were greatest when the MVA-gD2 vector was used as the priming immunization and then was boosted with either pgD2 or MVA-gD2. Determination of the isotype profile of MVA-gD2-primed mice revealed a much broader distribution of isotypes than that seen after DNA vaccination. In addition, antigen-stimulated spleen cells from mice primed with MVA-gD2 and boosted with either MVA-gD2 or pgD2 produced higher levels of interleukin-2 and interferon-gamma than did those from pgD2-primed mice, indicating that a prime-boost immunization strategy that uses the MVA and plasmid DNA vector dramatically enhances and diversifies the humoral and cellular immune response to HSV-2 gD.

BHRF1, a viral homologue of the Bcl-2 oncogene, is conserved at both the sequence and functional level in different Epstein-Barr virus isolates.

BHRF 1, a component of the restricted early antigen (EA) complex of the Epstein-Barr virus (EBV) lytic cycle, encodes a 17 kDa putative transmembrane protein with both sequence and functional homology to the Bcl-2 proto-oncogene. To determine whether there was any sequence variation over the BHRF1 open reading frame (ORF), 15 EBV isolates from different geographical regions and from both healthy donors and patients with EBV-associated diseases were sequenced. A small number of base changes which resulted in amino acid substitutions in the BHRF1 protein were found relative to the prototype B95.8 EBV sequence and these were predominantly clustered near the amino terminus of the BHRF1 protein outside conserved domains identified in the Bcl-2 homologues. In transient transfection assays none of the mutations in the BHRF1 ORF from eight different EBV isolates had a significant effect on BHRF1 protein localization compared to the B95.8 BHRF1 protein. However, transient expression of the adenovirus 12 19K protein or Bcl-2 resulted in localization patterns distinct from that observed with BHRF1 protein. Whilst all eight EBV isolates and E1B-19K gave comparable levels of protection to the DNA-damaging agent cis-platin, Bcl-2 did not afford significant protection. Thus, despite several amino acid changes in the BHRF1 ORF of some of the EBV isolates studied, the ability of the protein to protect against cis-platin induced apoptosis is conserved. The highly conserved nature of BHRF1 amongst different EBV isolates at both the sequence and functional level supports the proposed important role of BHRF1 in delaying cell death, thereby maximizing the production of progeny virus and facilitating the establishment of virus persistence.

Antibodies to the A27 Protein of Vaccinia Virus Neutralize and Protect against Infection but Represent a Minor Component of Dryvax Vaccine-Induced Immunity

The smallpox vaccine Dryvax, which consists of replication-competent vaccinia virus, elicits antibodies that play a major role in protection. Several vaccinia proteins generate neutralizing antibodies, but their importance for protection is unknown. We investigated the potency of antibodies to the A27 protein of the mature virion in neutralization and protection experiments and the contributions of A27 antibodies to Dryvax-induced immunity. Using a recombinant A27 protein (rA27), we confirmed that A27 contains neutralizing determinants and that vaccinia immune globulin (VIG) derived from Dryvax recipients contains reactivity to A27. However, VIG neutralization was not significantly reduced when A27 antibodies were removed, and antibodies elicited by an rA27 enhanced the protection conferred by VIG in passive transfer experiments. These findings demonstrate that A27 antibodies do not represent the major fraction of neutralizing activity in VIG and suggest that immunity may be augmented by vaccines and immune globulins that include strong antibody responses to A27.

DNA immunization with a herpes simplex virus 2 bacterial artificial chromosome

Abstract Construction of a herpes simplex virus 2 (HSV-2) bacterial artificial chromosome (BAC) is described. BAC vector sequences were inserted into the thymidine kinase gene of HSV-2 by homologous recombination. DNA from cells infected with the resulting recombinant virus was transformed into E. coli, and colonies containing the HSV-2 BAC (HSV2-BAC) were isolated and analyzed for the expected genotype. HSV2-BAC DNA was infectious when transfected back into mammalian cells and the resulting virus was thymidine kinase negative. When used to immunize mice, the HSV2-BAC DNA elicited a strong HSV-2 specific antibody response that was equal to or greater than live virus immunization. Further, HSV2-BAC immunization was protective when animals were challenged with a lethal dose of virus. The utility of the HSV2-BAC for construction of recombinant virus genomes was demonstrated by elimination of the HSV-2 glycoprotein D (gD) gene. A recombinant HSV-2 BAC with the gD gene deleted was isolated and shown to be incapable of producing infectious virus following transfection unless an HSV gD gene was expressed in a complementing cell line. Immunization of mice with the HSV2 gD-BAC also elicited an HSV-2 specific antibody response and was protective. The results demonstrate the feasibility of DNA immunization with HSV-2 bacterial artificial chromosomes for replicating and nonreplicating candidate HSV-2 vaccines, as well as the utility of BAC technology for construction and maintenance of novel HSV-2 vaccines. The results further suggest that such technology will be a powerful tool for dissecting the immune response to HSV-2.

Comparative Evaluation of the Immune Responses and Protection Engendered by LC16m8 and Dryvax Smallpox Vaccines in a Mouse Model

ABSTRACT The immune response elicited by LC16m8, a candidate smallpox vaccine that was developed in Japan by cold selection during serial passage of the Lister vaccine virus in primary rabbit kidney cells, was compared to Dryvax in a mouse model. LC16m8 carries a mutation resulting in the truncation of the B5 protein, an important neutralizing target of the extracellular envelope form of vaccinia virus (EV). LC16m8 elicited a broad-spectrum immunoglobulin G (IgG) response that neutralized both EV and the intracellular mature form of vaccinia virus and provoked cell-mediated immune responses, including the activation of CD4+ and CD8+ cells, similarly to Dryvax. Mice inoculated with LC16m8 had detectable but low levels of anti-B5 IgG compared to Dryvax, but both Dryvax and LC16m8 sera neutralized vaccinia virus EV in vitro. A truncated B5 protein (∼8 kDa) was expressed abundantly in LC16m8-infected cells, and both murine immune sera and human vaccinia virus immunoglobulin recognized the truncated recombinant B5 protein in antigen-specific enzyme-linked immunosorbent assays. At a high-dose intranasal challenge (100 or 250 50% lethal doses), LC16m8 and Dryvax conferred similar levels of protection against vaccinia virus strain WR postvaccination. Taken together, the results extend our current understanding of the protective immune responses elicited by LC16m8 and indicate that the relative efficacy in a mouse model rivals that of previously licensed smallpox vaccines.

Herpesvirus papio encodes a functional homologue of the Epstein-Barr virus apoptosis suppressor, BHRF1

The human tumour virus Epstein-Barr virus (EBV) encodes a 17 kDa protein, BHRF1, which is a member of the BCL:-2 family and has been shown to suppress apoptosis. The role of this gene in the life-cycle of EBV has not been fully elucidated. In order to identify motifs conserved in herpesviruses and possibly shed light on its function we isolated a BHRF1 homologue from herpesvirus papio (cercopithecine herpesvirus-12) a closely related gammaherpesvirus of baboons. The gene, hvpBHRF1, also encodes a 17 kDa protein which shares 64% identity and 79% similarity with EBV BHRF1 at the amino acid level. In biological assays, hvpBHRF1 and BHRF1 conferred similar levels of protection on human keratinocytes induced to apoptose with cis-platin.

Vaccinia Virus Nicking-Joining Enzyme Is Encoded by K4L (VACWR035)

ABSTRACT Vaccinia virus encodes an enzyme with DNA modifying activity that cleaves and inefficiently cross-links cruciformic DNA. This enzyme is contained within the virion, expressed at late times postinfection, and processes DNA in an energy-independent, Mg2+ ion-independent manner. Viral nuclease activity was measured in extracts from cells infected with well-defined viral mutants. Since some viral extracts lacked nuclease activity, the gene encoding the activity was postulated to be one of the open reading frames absent in the viruses lacking activity. Inducible expression of each candidate open reading frame revealed that only the gene VACWR035, or K4L, was required for nuclease activity. A recombinant virus missing only the open reading frame for K4L lacked nuclease activity. Extracts from a recombinant virus expressing K4L linked to a FLAG polypeptide were able to cleave and cross-link cruciformic DNA. There were no significant differences between the virus lacking K4L and wild-type vaccinia virus WR with respect to infectivity, growth characteristics, or processing of viral replicative intermediate DNA, including both telomeric and cross-linked forms. Purification of the K4L FLAG polypeptide expressed in bacteria yielded protein containing nicking-joining activity, implying that K4L is the only vaccinia virus protein required for the nicking-joining enzymatic activity.

Passive Immunotherapies Protect WRvFire and IHD-J-Luc Vaccinia Virus-Infected Mice from Lethality by Reducing Viral Loads in the Upper Respiratory Tract and Internal Organs

ABSTRACT Whole-body bioimaging was employed to study the effects of passive immunotherapies on lethality and viral dissemination in BALB/c mice challenged with recombinant vaccinia viruses expressing luciferase. WRvFire and IHD-J-Luc vaccinia viruses induced lethality with similar times to death following intranasal infection, but WRvFire replicated at higher levels than IHD-J-Luc in the upper and lower respiratory tracts. Three types of therapies were tested: licensed human anti-vaccinia virus immunoglobulin intravenous (VIGIV); recombinant anti-vaccinia virus immunoglobulin (rVIG; Symphogen, Denmark), an investigational product containing a mixture of 26 human monoclonal antibodies (HuMAbs) against mature virion (MV) and enveloped virion (EV); and HuMAb compositions targeting subsets of MV or EV proteins. Bioluminescence recorded daily showed that pretreatment with VIGIV (30 mg) or with rVIG (100 μg) on day −2 protected mice from death but did not prevent viral replication at the site of inoculation and dissemination to internal organs. Compositions containing HuMAbs against MV or EV proteins were protective in both infection models at 100 μg per animal, but at 30 μg, only anti-EV antibodies conferred protection. Importantly, the t statistic of the mean total fluxes revealed that viral loads in surviving mice were significantly reduced in at least 3 sites for 3 consecutive days (days 3 to 5) postchallenge, while significant reduction for 1 or 2 days in any individual site did not confer protection. Our data suggest that reduction of viral replication at multiple sites, including respiratory tract, spleen, and liver, as monitored by whole-body bioluminescence can be used to predict the effectiveness of passive immunotherapies in mouse models.

Antibodies to Antigenic Site A of Influenza H7 Hemagglutinin Provide Protection against H7N9 Challenge

Identifying major antigenic and protective epitopes of the H7 hemagglutinin (HA) will be important for understanding the antibody response to vaccines developed against the novel influenza H7N9 viruses that emerged in China in 2013. To facilitate antigenic characterization of the H7N9 HA and to develop reagents for evaluation of H7N9 candidate vaccines, we generated a panel of murine monoclonal antibodies (mAbs) to the HA of A/Shanghai/2/2013 using mammalian cell-derived virus-like particles (VLP) containing the H7 HA. Neutralizing antibodies identified an HA epitope corresponding to antigenic site A on the structurally similar influenza H3 hemagglutinin. Importantly, the neutralizing antibodies protect against A/Shanghai/2/2013 challenge. This antigenic site is conserved among many H7 viruses, including strains of both Eurasian and North American lineage, and the isolated neutralizing antibodies are cross-reactive with older H7 vaccine strains. The results indicate that the identified antigenic site is a potentially important protective epitope and suggest the potential benefit of cross-reactive antibody responses to vaccination with H7 candidate vaccines.