Expression of the major glycoprotein G of human respiratory syncytial virus from recombinant vaccinia virus vectors

New Insights on Respiratory Syncytial Virus Prevention

Respiratory syncytial virus (RSV) is a well-known infant pathogen transmitted mainly by droplets. It is a leading cause of upper respiratory tract infections in children, usually with a mild course of illness. RSV has also been a threat to older people, especially those with underlying medical conditions. For a long time, prevention was limited to passive immunoprophylaxis with palivizumab for high-risk infants. There was a strong need to find other treatment or prevention methods against RSV infections. In addition, after the coronavirus disease 2019 (COVID-19) pandemic, some significant changes in RSV epidemiology have been observed. Researchers noticed the shift in RSV seasonality and age distribution and the increased number of cases in older infants and adults. All of these made the need to find other medical options even stronger. Fortunately, two protein-based vaccines against RSV have successfully passed all phases of clinical trials and have been approved for use by adults and older people. One of them is also approved for infants from birth to 6 months of age (after maternal immunisation during pregnancy) and for pregnant women between 24 and 36 weeks of pregnancy. Also, a new passive immunisation option named nirsevimab (a highly potent monoclonal antibody with a long half-life) is now available for the paediatric group. In this review, we will discuss the previous and current RSV prevention methods in the light of structural discoveries of RSV antigens.

Respiratory syncytial virus limits alpha subunit of eukaryotic translation initiation factor 2 (eIF2alpha) phosphorylation to maintain translation and viral replication

The impact of respiratory syncytial virus (RSV) on morbidity and mortality is significant in that it causes bronchiolitis in infants, exacerbations in patients with obstructive lung disease, and pneumonia in immunocompromised hosts. RSV activates protein kinase R (PKR), a cellular kinase relevant to limiting viral replication (Groskreutz, D. J., Monick, M. M., Powers, L. S., Yarovinsky, T. O., Look, D. C., and Hunninghake, G. W. (2006) J. Immunol. 176, 1733-1740). It is activated by autophosphorylation, likely triggered by a double-stranded RNA intermediate during replication of the virus. In most instances, ph-PKR targets the alpha subunit of eukaryotic translation initiation factor 2 (eIF2alpha) protein via phosphorylation, leading to an inhibition of translation of cellular and viral protein. However, we found that although ph-PKR increases in RSV infection, significant eIF2alpha phosphorylation is not observed, and inhibition of protein translation does not occur. RSV infection attenuates eIF2alpha phosphorylation by favoring phosphatase rather than kinase activity. Although PKR is activated, RSV sequesters PKR away from eIF2alpha by binding of the kinase to the RSV N protein. This occurs in conjunction with an increase in the association of the phosphatase, PP2A, with eIF2alpha following PKR activation. The result is limited phosphorylation of eIF2alpha and continued translation of cellular and viral proteins.

Proliferative expansion and acquisition of effector activity by memory CD4+ T cells in the lungs following pulmonary virus infection

The memory CD4+ T cell response to the respiratory syncytial virus (RSV) attachment (G) protein in the lungs of primed BALB/c mice undergoing challenge pulmonary RSV infection is dominated by effector T cells expressing a single Vbeta-chain, Vbeta14. We have used Vbeta14 expression to examine the kinetics of the activation, accumulation, and acquisition of the effector activity of memory CD4+ T cells responding to pulmonary infection. This analysis revealed that proliferative expansion and effector CD4+ T cell differentiation preferentially occur in the respiratory tract following rapid activation within and egress from the lymph nodes draining the respiratory tract. These findings suggest that, in response to natural infection at a peripheral mucosal site such as the lungs, memory CD4+ T cell expansion and differentiation into activated effector T cells may occur predominantly in the peripheral site of infection rather than exclusively in the lymph nodes draining the site of infection.

Respiratory syncytial virus F envelope protein associates with lipid rafts without a requirement for other virus proteins

Like many enveloped viruses, human respiratory syncytial virus (RSV) assembles at and buds from lipid rafts. Translocation of the envelope proteins to these membrane subdomains is essential for production of infectious virus, but the targeting mechanism is poorly understood and it is not known if other virus proteins are required. Here we demonstrate that F protein of RSV intrinsically targets to lipid rafts without a requirement for any other virus protein, including the SH and G envelope proteins. Recombinant virus deficient in SH and G but retaining F protein expression was used to demonstrate that F protein still localized in rafts in both A549 and HEp-2 cells. Expression of a recombinant F gene by use of plasmid vectors demonstrated that F contains its own targeting domain and localized to rafts in the absence of other virus proteins. The domain responsible for translocation was then mapped. Unlike most other virus envelope proteins, F is unusual since the target signal is not contained within the cytoplasmic domain nor did it involve fatty acid modified residues. Furthermore, exchange of the transmembrane domain with that of the vesicular stomatitis virus G protein, a nonraft protein, did not alter F protein raft localization. Taken together, these data suggest that domains present in the extracellular portion of the protein are responsible for lipid raft targeting of the RSV F protein.

Respiratory syncytial virus nonstructural protein 2 specifically inhibits type I interferon signal transduction

Human respiratory syncytial virus (RSV) inhibits type I interferon-induced gene expression by decreasing expression of signal transducer and activator of transcription (Stat)2. To identify the RSV protein that mediates effects on Stat2, airway epithelial cells were infected with vaccinia virus vectors that express single RSV proteins. Expression of RSV nonstructural (NS)2 protein alone was sufficient to decrease Stat2 levels. Furthermore, decreasing RSV NS2 levels using RNA interference in respiratory epithelial cells inhibited the RSV-mediated decrease in Stat2 expression. Airway epithelial cells were also infected with equivalent inoculums of RSV without or with single gene deletions of NS1 or NS2. RSV infection without NS2 expression did not result in decreased Stat2 levels or loss of type I interferon-dependent signaling, indicating that NS2 expression is necessary for RSV effects on Stat2. Taken together, our results indicate that NS2 regulates Stat2 levels during RSV infection, thereby modulating viral effects on interferon-dependent gene expression.

Surfactant protein-d enhances phagocytosis and pulmonary clearance of respiratory syncytial virus

Surfactant protein (SP)-D gene targeted (SP-D-/-) and wild-type mice were infected with respiratory syncytial virus (RSV) by intratracheal instillation. Decreased clearance of RSV was observed in SP-D-/- mice. Deficiency of SP-D was associated with increased inflammation and inflammatory cell recruitment in the lung after infection. In vitro, SP-D bound RSV-infected Vero cells. Binding was inhibited with ethylenediamine tetraacetic acid and maltose, suggesting that the carbohydrate recognition domain of SP-D recognizes RSV glycoproteins in a calcium-dependent manner. SP-D bound specifically to the RSV proteins G and F. Phagocytosis of RSV by alveolar macrophages was reduced in the absence of SP-D in vivo, and SP-D enhanced phagocytosis of RSV by alveolar macrophages and neutrophils but not peritoneal macrophages in vitro. Oxygen radical production by alveolar macrophages from SP-D+/+ and SP-D-/- mice was decreased after RSV infection, and SP-D ameliorated the inhibitory effects of RSV on oxygen radical production by macrophages and neutrophils in vitro. Because the airway is the usual portal of entry for RSV and other respiratory pathogens, the local production of SP-D is likely to play a role in innate defense responses to inhaled viruses.

Sensitive detection and quantitation of mouse eosinophils in tissues using an enzymatic eosinophil peroxidase assay: its use to rapidly measure pulmonary eosinophilia during experimental respiratory syncytial virus infection of mice

Eosinophils are granular proinflammatory leukocytes implicated in the pathogenesis of several inflammatory processes including allergy, asthma, and in the development of enhanced disease during respiratory syncytial virus (RSV) infection. Here, we adapted a colorimetric assay to measure eosinophil peroxidase (EPO) activity in inflamed mouse lung tissue in order to quantitate pulmonary eosinophilia during experimental RSV infection. Using the substrate o-phenylenediamine dihydrochloride (OPD) in the presence of bromide ions, we show that this assay is able to quantitate limiting numbers of eosinophils in lung tissue homogenates even in the presence of large numbers of infiltrating neutrophils and macrophages. The ability of the EPO assay to selectively quantitate eosinophils in a complex tissue inflammatory infiltrate demonstrates the usefulness of this enzymatic assay as a rapid and sensitive method to quantitate the influx of eosinophils into inflamed mouse tissue such as the lung during experimental RSV infection without reliance on morphologic criteria to identify murine eosinophils in tissues or bronchial lavage fluid.

The attachment (G) glycoprotein of respiratory syncytial virus contains a single immunodominant epitope that elicits both Th1 and Th2 CD4+ T cell responses

BALB/c mice immunized with a vaccinia virus expressing the attachment (G) glycoprotein of respiratory syncytial virus (RSV) develop a virus-specific CD4(+) T cell response that consists of a mixture of Th1 and Th2 CD4(+) T cells following intranasal infection with live RSV. Recent work has shown that both Th1 and Th2 CD4(+) T cells are elicited to a single region comprising aa 183-197 of the G protein. To more precisely define the CD4(+) T cell epitope(s) contained within this region, we created a panel of amino- and carboxyl-terminal truncated as well as single alanine-substituted peptides spanning aa 183-197. These peptides were used to examine the ex vivo cytokine response of memory effector CD4(+) T cells infiltrating the lungs of G-primed RSV-infected mice. Analysis of lung-derived memory effector CD4(+) T cells using intracellular cytokine staining and/or ELISA of effector T cell culture supernatants revealed a single I-E(d)-restricted CD4(+) T cell epitope with a core sequence mapping to aa 185-193. In addition, we examined the T cell repertoire of the RSV G peptide-specific CD4(+) T cells and show that the CD4(+) T cells directed to this single immunodominant G epitope use a restricted range of TCR Vss genes and predominantly express Vss14 TCR.

Secreted respiratory syncytial virus G glycoprotein induces interleukin-5 (IL-5), IL-13, and eosinophilia by an IL-4-independent mechanism

The attachment glycoprotein G of respiratory syncytial virus (RSV) is produced as both membrane-anchored and secreted forms by infected cells. Immunization with secreted RSV G (Gs) or formalin-inactivated alumprecipitated RSV (FI-RSV) predisposes mice to immune responses involving a Th2 cell phenotype which results in more severe illness and pathology, decreased viral clearance, and increased pulmonary eosinophilia upon subsequent RSV challenge. These responses are associated with increased interleukin-4 (IL-4) production in FI-RSV-primed mice, and the responses are IL-4 dependent. RNase protection assays demonstrated that similar levels of IL-4 mRNA were induced after RSV challenge in mice primed with vaccinia virus expressing Gs (vvGs) or a construct expressing only membrane-anchored G (vvGr). However, upon RSV challenge, vvGs-primed mice produced significantly greater levels of IL-5 and IL-13 mRNA and protein than vvGr-primed mice. Administration of neutralizing anti-IL-4 antibody 11.B11 during vaccinia virus priming did not alter the levels of vvGs-induced IL-5, IL-13, pulmonary eosinophilia, illness, or RSV titers upon RSV challenge, although immunoglobulin G (IgG) isotype profiles revealed that more IgG2a was produced. vvGs-priming of IL-4-deficient mice demonstrated that G-induced airway eosinophilia was not dependent on IL-4. In contrast, airway eosinophilia induced by FI-RSV priming was significantly reduced in IL-4-deficient mice. Thus we conclude that, in contrast to FI-RSV, the secreted form of RSV G can directly induce IL-5 and IL-13, producing pulmonary eosinophilia and enhanced illness in RSV-challenged mice by an IL-4-independent mechanism.

Induction of Th-1 and Th-2 responses by respiratory syncytial virus attachment glycoprotein is epitope and major histocompatibility complex independent

In BALB/c mice, sensitization to respiratory syncytial virus (RSV) attachment (G) glycoprotein leads to the development of lung eosinophilia upon challenge infection with RSV, a pathology indicative of a strong in vivo induction of a Th-2-type response. In this study, we found that a strong, RSV G-specific, Th-1-type cytokine response occurred simultaneously with a Th-2-type response in G-primed mice after RSV challenge. Both Th-1 and Th-2 effector CD4(+) T cells recognized a single immunodominant site on this protein, implying that the differentiation of memory CD4(+) T cells along the Th-1 or Th-2 effector pathway was independent of the epitope specificity of the T cells. A similar observation was made in G-primed H-2(b) haplotype mice after RSV challenge, further suggesting that this process is not dependent on the peptide epitope presented. On the other hand, genes mapping to loci outside of the major histocompatibility complex region are crucial regulators of the development of a Th-2-type response and lung eosinophilia. The implication of these findings for the immune mechanisms underlying the pathogenesis of RSV is discussed.

Priming with secreted glycoprotein G of respiratory syncytial virus (RSV) augments interleukin-5 production and tissue eosinophilia after RSV challenge

The respiratory syncytial virus (RSV) G glycoprotein promotes differentiation of type 2 CD4+ T lymphocytes and induces an eosinophilic response in lungs of RSV-infected mice. A unique feature of G is that a second initiation codon in the transmembrane region of the glycoprotein results in secretion of soluble protein from infected cells. Recombinant vaccinia viruses that express wild-type G (vvWT G), only secreted G (vvM48), or only membrane-anchored G (vvM48I) were used to define the influence of G priming on immunopathogenesis. Mice immunized with vvM48 had more severe illness following RSV challenge than did mice primed with vvWT G or vvM48I. Coadministration of purified G during priming with the construct expressing membrane-anchored G shifted immune responses following RSV challenge to a more Th2-like response. This was characterized by increased interleukin-5 in lung supernatants and an increase in G-specific immunoglobulin G1 antibodies. Eosinophils were present in the infiltrate of all mice primed with G-containing vectors but were greatest in mice primed with regimens including secreted G. These data suggest the form of G protein available for initial antigen processing and presentation is an important factor in promoting Th2-like immune responses, including the induction of lung eosinophilia. The ability of RSV to secrete G protein may therefore represent a viral strategy for immunomodulation and be a key determinant of disease pathogenesis.

Virus-specific CD8+ T lymphocytes downregulate T helper cell type 2 cytokine secretion and pulmonary eosinophilia during experimental murine respiratory syncytial virus infection

T lymphocytes play a pivotal role in the immune response during viral infections. In a murine model of experimental respiratory syncytial virus (RSV) infection, mice sensitized to either of the two major glycoproteins of RSV develop distinct patterns of cytokine secretion and lung inflammation upon subsequent RSV infection. Mice sensitized to RSV-G (attachment) glycoprotein exhibit a strong interleukin (IL)-4 and IL-5 response and develop pulmonary eosinophilia, whereas mice sensitized to RSV-F (fusion) glycoprotein develop a predominantly T helper cell (Th)1 response and pulmonary inflammation characterized by mononuclear cell infiltration. In this study, we examined the potential role of virus-specific CD8+ T cytolytic T cells on the differentiation and activation of functionally distinct CD4+ T cells specific to these viral glycoproteins. Mice primed with recombinant vaccinia virus expressing RSV-F glycoprotein mounted a strong RSV-specific, MHC class I-restricted cytolytic response, whereas priming with recombinant vaccinia virus expressing RSV-G glycoprotein failed to elicit any detectable cytolytic response. Priming for a RSV-specific CD8+ T cell response, either with a recombinant vaccinia virus expressing RSV-G glycoprotein in which a strong CD8+ T cell epitope from RSV-M2 (matrix) protein has been inserted or with a combination of vaccinia virus expressing the matrix protein and the RSV-G glycoprotein, suppressed the eosinophil recruitment into the lungs of these mice upon subsequent challenge with RSV. This reduction in pulmonary eosinophilia correlated with the suppression of Th2 type cytokine production. The importance of CD8+ T cells in this process was further supported by the results in CD8+ T cell deficient, beta 2 microglobulin KO mice. In these mice, priming to RSV-F glycoprotein (which in normal mice primed for a strong cytolytic response and a pulmonary infiltrate consisting primarily of mononuclear cells on RSV challenge) resulted in the development of marked pulmonary eosinophilia that was not seen in mice with an intact CD8+ T cell compartment. These results indicate that CD8+ T cells may play an important role in the regulation of the differentiation and activation of Th2 CD4+ T cells as well as the recruitment of eosinophils into the lungs during RSV infection.

Virus-specific memory and effector T lymphocytes exhibit different cytokine responses to antigens during experimental murine respiratory syncytial virus infection

Mice sensitized to the G (attachment) or F (fusion) glycoproteins of respiratory syncytial virus (RSV) expressed different patterns of cytokine production and lung pathology when challenged by intranasal infection with RSV. Five days after challenge, mice sensitized to G glycoprotein produced high levels of interleukin-4 (IL-4) and IL-5 in the lungs and spleens and developed extensive pulmonary eosinophilia, while mice sensitized to F glycoprotein produced IL-2 and developed a mononuclear cell infiltration. Memory lymphocytes isolated 2 weeks after intranasal challenge of mice primed to the G or F glycoprotein secreted only IL-2 and gamma interferon (IFN-gamma) when stimulated with RSV. IL-4 and IL-5 production characteristic of Th2-type effectors in the lung was observed only after multiple rounds of in vitro stimulation of RSV G-specific memory T lymphocytes with antigen. Also IFN-gamma production appeared to play only a minor role in the expression of pulmonary pathology characteristic of Th1 or Th2 T-lymphocyte responses, because mice genetically deficient in IFN-gamma production by gene disruption displayed the same pattern of pulmonary inflammation to RSV infection after priming to RSV F or G as conventional mice. These results suggest that effector T lymphocytes exhibit a different pattern of cytokine production than memory T-lymphocyte precursors precommitted to a Th1 or Th2 pattern of differentiation. Furthermore, these observations raise the possibility that the cytokine response of human memory T lymphocytes after a single exposure to antigen in vitro may not accurately reflect the cytokine response of differentiated effector T lymphocytes at the site of infection in vivo.

The membrane-associated and secreted forms of the respiratory syncytial virus attachment glycoprotein G are synthesized from alternative initiation codons

Respiratory syncytial (RS) virus synthesizes two mature forms of its attachment glycoprotein G: an anchored type II integral membrane form and a smaller form that is secreted into the medium. Here we demonstrate that these two forms are synthesized as distinct primary translation products of a single species of G protein mRNA by initiation at either of two different AUGs. Mutant cDNAs which eliminated one of the other of the two AUG codons near the 5' end of the G gene open reading frame were constructed. Analysis of the proteins synthesized from these cDNAs, either by translation of transcripts in a cell-free system or in cells infected with recombinant vaccinia viruses containing either one of the mutant cDNAs, showed that elimination of either the first or the second of these AUG codons abrogated the synthesis of the membrane-anchored or the secreted form of the protein, respectively. Additionally, two unglycosylated forms of G protein which comigrated with the unglycosylated G proteins expressed by these recombinant viruses were detected in RS virus-infected cells. Since the second AUG encodes a methionine residue that lies near the middle of the signal/anchor domain, initiation at this codon resulted in a protein with a hydrophobic amino terminus. This form of the glycoprotein was efficiently secreted from cells infected with the vaccinia virus recombinant, and the amino-terminal sequence of this protein was identical to that of G protein secreted from RS virus-infected cells. Our results demonstrate that the secreted form of RS virus G protein is produced by initiation at the second AUG codon of the G open reading frame, followed by proteolytic removal of the signal/anchor domain.

Nodavirus RNA replication: mechanism and harnessing to vaccinia virus recombinants

In order to harness RNA replication for the amplification of mRNAs expressed from recombinant vectors and vaccines, we constructed a VV recombinant that expressed the RNA replicase encoded in the larger genomic segment of the nodavirus FHV. When both termini of the VV-derived transcript were correct, the encoded enzyme replicated its own mRNA, and replication dominated the RNA synthetic capacity of the cell. The smaller genomic segment of FHV could also be replicated by the enzyme when supplied in trans, either by coinfection with another VV recombinant or by transfection of an appropriate plasmid. However, two requirements had to be fulfilled for replication of the smaller FHV RNA segment. The first was the prior replication of the larger genomic segment, which was interpreted as a mechanism to achieve sufficient replicase synthesis before the onset of coat protein synthesis. The second was the presence in the smaller genomic RNA of an internal region between about nucleotides 525-620. Work is in progress to elucidate the reasons for these requirements for RNA 2 replication.

Distinct types of lung disease caused by functional subsets of antiviral T cells

T cells appear to play a central role in viral bronchiolitis, but the effects of different functional and phenotypic subgroups of T cells have not been defined. To test the activities of T cells recognizing individual proteins of respiratory syncytial (RS) virus, virus-specific T cell lines were produced from mice primed by scarification with recombinant vaccinia viruses expressing the major surface glycoprotein (G), fusion protein (F) or second matrix (22K) protein of RS virus. As previously reported, the in vitro characteristics of these cells are predetermined by the choice of RS virus protein: 22K-specific cells are predominantly class I-restricted cytolytic CD8+ cells; F-specific cells, a mixture of cytolytic CD8+ cells and CD4+ cells with a T helper 1 cell (Th1) cytokine secretion profile, whereas those from G-sensitized mice are almost exclusively CD4+, with Th2 characteristics. Mice infected intranasally with RS virus showed mild illness and recovered fully, but developed respiratory distress after intravenous injections of T cells. Dose-for-dose, infected mice receiving G-specific cells suffered the most severe (sometimes fatal) illness, characterized by lung hemorrhage, pulmonary neutrophil recruitment (shock lung) and intense pulmonary eosinophilia. This disease was further enhanced by coinjection of 22K-specific cells, which alone caused mild shock lung without eosinophilia. F-specific cells caused minimal enhancement of pathology and had little or no effect on the disease caused by G-specific cells. Each cell line reduced lung virus titer and combined injections of G- and 22K-specific cells eliminated infection completely. The in vitro characteristics of these antiviral T cell lines therefore predict the pathological effects in vivo. Moreover, different forms of viral bronchiolitis can be caused by functionally distinct types of activated T cell.

Protection of macaques against infection with simian type D retrovirus (SRV-1) by immunization with recombinant vaccinia virus expressing the envelope glycoproteins of either SRV-1 or Mason-Pfizer monkey virus (SRV-3)

Rhesus macaques were immunized with live vaccinia virus recombinants expressing the envelope glycoproteins (gp70 and gp22) of simian type D retrovirus (SRV), serotype 1 or 3. All of the animals immunized with either the SRV-1 env or the SRV-3 env vaccinia virus recombinant developed neutralizing antibodies against the homologous SRV. In addition, both groups developed cross-reactive antibodies and were protected against an intravenous live-virus challenge with SRV-1. The four control animals immunized with a vaccinia virus recombinant expressing the G protein of respiratory syncytial virus were not protected against the same SRV-1 challenge. Although SRV-1 and SRV-3 immune sera showed cross-neutralization, they failed to neutralize a separate, more distantly related serotype, SRV-2, in an in vitro assay. These findings are consistent with the known degree of serologic and genetic relatedness of these three SRV strains.

Human cytotoxic T cells stimulated by antigen on dendritic cells recognize the N, SH, F, M, 22K, and 1b proteins of respiratory syncytial virus

We examined the human cytotoxic T-cell repertoire of nine adults to 9 of the 10 proteins of respiratory syncytial (RS) virus. Peripheral blood mononuclear cells from normal adults were stimulated with RS virus in vitro. The resulting polyclonal cultures were tested for lysis of B-lymphoblastoid cell lines infected with recombinant vaccinia viruses expressing each of nine individual RS virus proteins. The use of peripheral blood dendritic cells to present antigen gave more easily reproducible results over a shorter culture period than conventional methods. The six RS virus proteins most strongly recognized were the nucleoprotein N (nine of nine donors with greater than 10% above background lysis; P = 0.0004), the surface proteins SH (six of nine donors; P = 0.002) and F (five of nine donors; P = 0.008), the matrix proteins M (five of nine donors; P = 0.004) and 22K (three of nine donors; P = 0.01) and the nonstructural protein 1b (six of nine donors; P = 0.004). There was no significant recognition of the major surface glycoprotein G (two of nine donors), the internal phosphoprotein P (one of nine donors), or the nonstructural protein 1c (one of nine donors). Recognition was major histocompatibility complex class I restricted, but no association between major histocompatibility complex phenotype and protein specificity of T cells was seen. Recognition of F and 22K appeared to be associated with recent infection indicated by increased levels of anti-RS virus immunoglobulin G antibody in serum measured by enzyme-linked immunosorbent assay. Since cytotoxic T-cell recognition of RS virus proteins has been demonstrated to be important in the clearance of virus from infected hosts, the N, M, SH, 1b, F, and 22K proteins should be considered potential vaccine components.

Nucleotide sequence analysis and expression from recombinant vectors demonstrate that the attachment protein G of bovine respiratory syncytial virus is distinct from that of human respiratory syncytial virus

Bovine respiratory syncytial (BRS) virus causes a severe lower respiratory tract disease in calves similar to the disease in children caused by human respiratory syncytial (HRS) virus. While there is antigenic cross-reactivity among the other major viral structural proteins, the major glycoprotein, G, of BRS virus and that of HRS virus are antigenically distinct. The G glycoprotein has been implicated as the attachment protein for HRS virus. We have carried out a molecular comparison of the glycoprotein G of BRS virus with the HRS virus counterparts. cDNA clones corresponding to the BRS virus G glycoprotein mRNA were isolated and analyzed by dideoxynucleotide sequencing. The BRS virus G mRNA contained 838 nucleotides exclusive of poly(A) and had a major open reading frame coding for a polypeptide of 257 amino acid residues. The deduced amino acid sequence of the BRS virus G polypeptide showed only 29 to 30% amino acid identity with the G protein of either the subgroup A or B HRS virus. However, despite this low level of identity, there were strong similarities in the predicted hydropathy profiles of the BRS virus and HRS virus G proteins. A cDNA molecule containing the complete BRS virus G major open reading frame was inserted into the thymidine kinase gene of vaccinia virus by homologous recombination, and a recombinant virus containing the BRS virus G protein gene was isolated. This recombinant virus expressed the BRS virus G protein, as demonstrated by Western immunoblot analysis and immunofluorescence of infected cells. The BRS virus G protein expressed from the recombinant vector was transported to and expressed on the surface of infected cells. Antisera to the BRS virus G protein made by using the recombinant vector to immunize animals recognized the BRS virus attachment protein but not the HRS virus G protein and vice versa, confirming the lack of antigenic cross-reactivity between the BRS and HRS virus attachment proteins. On the basis of the data presented here, we conclude that BRS virus should be classified within the genus Pneumovirus in a group separate from HRS virus and that it is no more closely related to HRS virus subgroup A than it is to HRS virus subgroup B.

Vaccinia virus vectors: new strategies for producing recombinant vaccines

The development and continued refinement of techniques for the efficient insertion and expression of heterologous DNA sequences from within the genomic context of infectious vaccinia virus recombinants are among the most promising current approaches towards effective immunoprophylaxis against a variety of protozoan, viral, and bacterial human pathogens. Because of its medical relevance, this area is the subject of intense research interest and has evolved rapidly during the past several years. This review (i) provides an updated overview of the technology that exists for assembling recombinant vaccinia virus strains, (ii) discusses the advantages and disadvantages of these approaches, (iii) outlines the areas of outgoing research directed towards overcoming the limitations of current techniques, and (iv) provides some insight (i.e., speculation) about probable future refinements in the use of vaccinia virus as a vector.

Limited expression of poliovirus by vaccinia virus recombinants due to inhibition of the vector by proteinase 2A

A recombinant vaccinia virus was constructed that expressed poliovirus coat precursor protein P1 fused to about two-thirds of the 2A proteinase. The truncated 2A segment could be cleaved away from the P1 region by coinfecting with poliovirus type 1, 2, or 3 or with human rhinovirus 14 but not with encephalomyocarditis virus. Further cleavage of the vector-derived P1 to yield mature poliovirus capsid proteins was not observed. Attempts to isolate vaccinia virus recombinants containing portions of the poliovirus genome that encompassed the complete gene for proteinase 2A were unsuccessful, unless expression of functional 2A was abolished by insertion of a frameshift mutation. We conclude that an activity of the 2A proteinase, probably its role in translational inhibition, prevented isolation of vaccinia virus recombinants that expressed 2A.

Structure and cell surface maturation of the attachment glycoprotein of human respiratory syncytial virus in a cell line deficient in O glycosylation

The synthesis of the extensively O-glycosylated attachment protein, G, of human respiratory syncytial virus and its expression on the cell surface were examined in a mutant Chinese hamster ovary (CHO) cell line, ldlD, which has a defect in protein O glycosylation. These cells, used in conjunction with an inhibitor of N-linked oligosaccharide synthesis, can be used to establish conditions in which no carbohydrate addition occurs or in which either N-linked or O-linked carbohydrate addition occurs exclusively. A recombinant vaccinia virus expression vector for the G protein was constructed which, as well as containing the human respiratory syncytial virus G gene, contained a portion of the cowpox virus genome that circumvents the normal host range restriction of vaccinia virus in CHO cells. The recombinant vector expressed high levels of G protein in both mutant ldlD and wild-type CHO cells. Several immature forms of the G protein were identified that contained exclusively N-linked or O-linked oligosaccharide side chains. Metabolic pulse-chase studies indicated that the pathway of maturation for the G protein proceeds from synthesis of the 32-kilodalton (kDa) polypeptide accompanied by cotranslational attachment of high-mannose N-linked sugars to form an intermediate with an apparent mass of 45 kDa. This step is followed by the Golgi-associated conversion of the N-linked sugars to the complex type and the completion of the O-linked oligosaccharides to achieve the mature 90-kDa form of G. Maturation from the 45-kDa N-linked form to the mature 90-kDa form occurred only in the presence of O-linked sugar addition, confirming that O-linked oligosaccharides constitute a significant proportion of the mass of the mature G protein. In the absence of O glycosylation, forms of G bearing galactose-deficient truncated N-linked and fully mature N-linked oligosaccharides were observed. The effects of N- and O-linked sugar addition on the transport of G to the cell surface were measured. Indirect immunofluorescence and flow cytometry showed that G protein could be expressed on the cell surface in the absence of either O glycosylation or N glycosylation. However, cell surface expression of G lacking both N- and O-linked oligosaccharides was severely depressed.

Synthesis, cellular location, and immunogenicity of bovine herpesvirus 1 glycoproteins gI and gIII expressed by recombinant vaccinia virus

Two of the major glycoproteins of bovine herpesvirus 1 (BHV-1) are gI, a polypeptide complex with apparent molecular weights of 130,000, 74,000, and 55,000, and gIII (a 91,000-molecular-weight [91K] glycoprotein), which also exists as a 180K dimer. Vaccinia virus (VAC) recombinants were constructed which carry full-length gI (VAC-I) or gIII (VAC-III) genes. The genes for gI and gIII were each placed under the control of the early VAC 7.5K gene promoter and inserted within the VAC gene for thymidine kinase. The recombinant viruses VAC-I and VAC-III retained infectivity and expressed both precursor and mature forms of glycoproteins gI and gIII. The polypeptide backbones, partially glycosylated precursors, and mature gI and gIII glycoproteins were indistinguishable from those produced in BHV-1-infected cells. Consequently, they were apparently cleaved, glycosylated, and transported in a manner similar to that seen during authentic BHV-1 infection, although the processing efficiencies of both gI and gIII were generally higher in recombinant-infected cells than in BHV-1-infected cells. Immunofluorescence studies further demonstrated that the mature gI and gIII glycoproteins were transported to and expressed on the surface of cells infected with the respective recombinants. Immunization of cattle with recombinant viruses VAC-I and VAC-III resulted in the induction of neutralizing antibodies to BHV-1, which were reactive with authentic gI and gIII. These data demonstrate the immunogenicity of VAC-expressed gI and gIII and indicate the potential of these recombinant glycoproteins as a vaccine against BHV-1.

Marked differences in the antigenic structure of human respiratory syncytial virus F and G glycoproteins

Monoclonal antibodies directed against the glycoproteins of human respiratory syncytial virus were used in competitive enzyme-linked immunosorbent assays for topological mapping of epitopes. Whereas epitopes of the F glycoprotein could be ascribed to five nonoverlapping antigenic sites, anti-G antibodies recognized unique epitopes, many of whose competition profiles overlapped extensively. Variant viruses selected with a neutralizing (47F) anti-F antibody lost the binding for only 47F and 49F antibodies, which mapped in the same antigenic area. In contrast, viruses selected with an anti-G antibody lost the capacity to bind most of the anti-G antibodies, and their G protein was not recognized by an anti-virus antiserum, indicating major changes in the antigenic structure of the G molecule. Finally, we found great antigenic variation of the G protein among viral isolates. This occurred even within viruses of the same subtype with only limited divergence of amino acid sequence between strains. All of these data indicate marked differences in the antigenic organization of the G and F glycoproteins of respiratory syncytial virus; we discuss these differences in terms of the chemical structure of the glycoproteins.

Primary respiratory syncytial virus infection in mice

A mouse model of respiratory syncytial virus (RSV) infection is described. A high-titered, large-volume inoculum results in replication of RSV to a high titer in lungs of BALB/c mice. Mice older than 15 weeks of age are more susceptible to RSV infection. Titers up to 10(6.9) plaque-forming units (pfu)/gram lung can be attained in 32-week-old mice. Older mice experience a clinical illness manifested by ruffled fur, reduced activity, and weight loss. Lung histology of older mice infected with RSV shows bronchiolitis and increased number of lymphocytes and macrophages in alveolar spaces compared with that of mice less than 8 weeks old. This model will serve as the basis for investigating immunodeterminants of recovery and protection from RSV infection.

Pneumovirus-like characteristics of the mRNA and proteins of turkey rhinotracheitis virus

Electronmicroscopy has indicated that turkey rhinotracheitis virus (TRTV), the causative agent of an acute respiratory disease in turkeys, is a member of the Paramyxoviridae family. To determine if TRTV belongs to one of the three defined genera of this family (Paramyxovirus, Morbillivirus and Pneumovirus) we have analysed the RNA and proteins induced during replication of TRTV in Vero cells. Following replication in the presence of actinomycin D 10 polyadenylated RNA bands, ranging in Mr from 0.22 to 2.0 X 10(6), were detected in infected cells; some bands probably contained 2 or more RNA species. Viral proteins were studied after radiolabelling in the presence of [35S]methionine and [3H]glucosamine. Comparison of the polypeptides in mock-infected and infected cells, virions and nucleocapsids and after lentil-lectin chromatography and immunoprecipitation revealed seven virus-specific polypeptides (p), some of which were glycosylated (gp): gp82 (Mr 82K), gp68, gp53, gp15, p43, p40 and p35. These are considered to be analogous to the large glycopolypeptide (HN, H and G), fusion protein precursor F0, the F protein cleavage products F1 and F2, nucleocapsid (N), phosphorylated (P) and matrix (M) polypeptides, respectively, of the Paramyxoviridae. Two other polypeptides (Mr 200K and 22K) were also detected, as was a glycopolypeptide of Mr 97K, probably related to gp82. Tunicamycin inhibited glycosylation of gp53 and gp15 but gp82 was little affected, most glycans still being present on a glycopolypeptide of approximately 79K. This finding, indicating that gp82 has mostly O-linked glycans, considered with the mRNA profile and the molecular weight of the N protein shows that of the three genera in this family, TRTV most closely resembles the Pneumovirus genus.

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.

Protection of mice from fatal measles encephalitis by vaccination with vaccinia virus recombinants encoding either the hemagglutinin or the fusion protein

Vaccinia virus recombinants encoding the hemagglutinin or fusion protein of measles virus have been constructed. Infection of cell cultures with the recombinants led to the synthesis of authentic measles proteins as judged by their electrophoretic mobility, recognition by antibodies, glycosylation, proteolytic cleavage, and presentation on the cell surface. Mice vaccinated with a single dose of the recombinant encoding the hemagglutinin protein developed antibodies capable of both inhibiting hemagglutination activity and neutralizing measles virus, whereas animals vaccinated with the recombinant encoding the fusion protein developed measles neutralizing antibodies. Mice vaccinated with either of the recombinants resisted a normally lethal intracerebral inoculation of a cell-associated measles virus subacute sclerosing panencephalitis strain.

Immune and histopathological responses in animals vaccinated with recombinant vaccinia viruses that express individual genes of human respiratory syncytial virus

Previous reports have established that vaccinia virus (VV) recombinants expressing G, F, or N protein of respiratory syncytial (RS) virus protect small animals against intranasal challenge with live RS virus. This work demonstrates that a variety of parameters affect the protection induced by recombinant viruses. The route of vaccination, the subtype of challenge virus, and the species used influenced the antibody titers and extent of protection. During these studies, observations were also made on the subclass of antibody generated, and pulmonary histopathological changes induced by challenge after vaccination were noted. The effect of route of inoculation on host response was examined by vaccinating mice intranasally, intraperitoneally, or by scarification with a recombinant VV expressing the RS virus G glycoprotein. Intranasal vaccination induced 25-fold-higher titers of antibody to RS virus in the lung than the intraperitoneal route did, but both routes resulted in complete suppression of virus replication after intranasal challenge 21 days after vaccination. Scarification was a less effective method of vaccination. The antibody induced by recombinant VV in mice was mostly immunoglobulin G2a (IgG2a) with some IgG2b. No antibody to RS virus was detected in the IgA, IgM, IgG1, or IgG3 subclass irrespective of the vaccination route. The G and F glycoproteins were shown to elicit similar subclasses of antibody. However, animals vaccinated with the G and F vectors differed strikingly in their response to challenge by heterologous virus. Mice or cotton rats vaccinated with recombinant VV carrying the G gene of RS virus were protected against challenge only with homologous subtype A virus. Vaccination with a recombinant VV expressing the F glycoprotein induced protection against both homologous and heterologous subtype B virus challenge. The protection induced in mice was greater than that detected in cotton rats, indicating that the host may also affect immunity. Finally, this report describes histological examination of mouse lungs after vaccination and challenge. Vaccinated mice that were subsequently challenged had significantly greater lung lesion scores than unvaccinated challenged mice. The lesions were primarily peribronchiolar and perivascular infiltrations of polymorphonuclear cells and lymphocytes. Further work will establish whether these pulmonary changes are a desirable immune response to virus invasion or a potential immunopathogenic hazard. The results have important implications for planning a strategy of vaccination against RS virus and emphasize potential dangers that may attend the use of recombinant VV as vaccines.

Antigenic relatedness between glycoproteins of human respiratory syncytial virus subgroups A and B: evaluation of the contributions of F and G glycoproteins to immunity

The degree of antigenic relatedness between human respiratory syncytial virus (RSV) subgroups A and B was estimated from antibody responses induced in cotton rats by respiratory tract infection with RSV. Glycoprotein-specific enzyme-linked immunosorbent assays of antibody responses induced by RSV infection demonstrated that the F glycoproteins of subgroups A and B were antigenically closely related (relatedness, R approximately 50%), whereas the G glycoproteins were only distantly related (R approximately 5%). Intermediate levels of antigenic relatedness (R approximately 25%) were seen in neutralizing antibodies from cotton rats infected with RSV of the two subgroups. Immunity against the F glycoprotein of subgroup A, induced by vaccinia-A2-F, conferred a high level of protection which was of comparable magnitude against challenge by RSV of either subgroup. In comparison, immunity against the G glycoprotein of subgroup A, induced by vaccinia-A2-G, conferred less complete, but significant, protection. Importantly, in vaccinia-A2-G-immunized animals, suppression of homologous challenge virus replication was significantly greater (13-fold) than that observed for the heterologous virus.

Recombinant vaccinia viruses carrying the N gene of human respiratory syncytial virus: studies of gene expression in cell culture and immune response in mice

The construction and characterization of vaccinia virus recombinants carrying the nucleocapsid (N) protein gene of human respiratory syncytial (RS) virus are described. Recombinant viruses were constructed that contained the N gene oriented either positively or negatively with respect to the 7.5-kilodalton vaccinia virus promoter. In addition, a positively oriented recombinant was constructed that lacked an out-of-frame AUG codon in the 5'-terminal noncoding region. In HEp-2 cells, both positive-orientation recombinants induced the synthesis of a protein which comigrated with N protein and was precipitated by antisera to RS virus. Sera from mice immunized with these recombinants specifically precipitated the RS virus N protein. Analysis of mRNA and protein expressed from the recombinant N genes showed that deletion of the upstream AUG codon markedly improved the efficiency of protein synthesis. Mice were vaccinated with the high-expressing recombinant and subsequently challenged with live RS virus. The results of these experiments demonstrated that the immune response to N protein afforded a significant degree of protection against RS virus disease.

High-frequency homologous recombination in vaccinia virus DNA

A recombinant vaccinia virus genome was constructed in which the viral thymidine kinase (tk) gene was placed between direct repeats of a 1.5-kilobase-pair DNA sequence of heterologous origin. When forced to replicate in tk- cells in the presence of methotrexate (i.e., under tk+-selective conditions), the recombinant maintained its tk+ phenotype. Under nonselective conditions, however, the tk gene was frequently excised by both inter- and intramolecular recombination events because the repeated sequences provided substantial targets for homologous DNA recombination. Unique DNA products of intramolecular recombination were detected in the cytoplasm of infected cells soon after the onset of viral DNA replication, and their appearance was blocked by inhibitors of DNA synthesis. During repeated passage of the virus under nonselective conditions, the tk+ fraction decreased with first-order kinetics at a rate that reflected the frequency of recombination per cycle of virus replication. Eventually, a residual population of stable tk+ viruses remained, and analyses of the genome structures of individual members of this population showed that some of them appeared to be the products of nonhomologous DNA recombination.

Expression of the fusion protein of human respiratory syncytial virus from recombinant vaccinia virus vectors and protection of vaccinated mice

Vaccinia virus (VV) recombinants were constructed that contained full-length cDNA copies of the fusion (F) protein gene of human respiratory syncytial (RS) virus. The F protein gene was placed next to the strong early-late VV 7.5-kilodalton promoter and was located within the VV thymidine kinase (tk) gene. Full-length recombinant transcripts that initiated at both the tk and the 7.5-kilodalton promoters accumulated in cells early in infection, and one or more of these transcripts was translated to yield a glycoprotein which comigrated with Fo, the fusion protein precursor. This precursor was processed by proteolytic cleavage to produce the two disulfide-linked subunits F1 and F2, which were both glycosylated and of the same electrophoretic mobility as authentic F1 and F2. Immunofluorescence studies demonstrated that the mature F protein was transported to and expressed on the surface of recombinant VV-infected cells. Inoculation of rabbits with a recombinant vector expressing F resulted in the production of antiserum specific for the RS virus F protein. This antiserum neutralized virus infectivity and was capable of preventing fusion in RS virus-infected cells. Mice were vaccinated with recombinants expressing the F protein. At 3 weeks postinoculation, these animals had serum antibody against RS virus F protein. At 5 days after intranasal challenge with RS virus, the lungs of the mice previously vaccinated with recombinants expressing F protein were free of detectable RS virus, whereas the lungs of unvaccinated mice contained 10(4.2) PFU of virus per g.

Human respiratory syncytial virus glycoprotein G expressed from a recombinant vaccinia virus vector protects mice against live-virus challenge

Recombinant vaccinia virus vectors were constructed which expressed the major surface glycoprotein G of human respiratory syncytial (RS) virus. The biological activity of the G protein expressed from these vectors was assayed. Inoculation of rabbits with live recombinant virus induced high titers of antibody which specifically immunoprecipitated RS virus G protein and was capable of neutralizing RS virus infectivity. Immunization of mice by either the intranasal or the intraperitoneal route with recombinant virus that expressed only the G protein resulted in complete protection of the lower respiratory tract upon subsequent challenge with live RS virus.

Expression of the F glycoprotein of respiratory syncytial virus by a recombinant vaccinia virus: comparison of the individual contributions of the F and G glycoproteins to host immunity

A cDNA clone representing the mRNA coding sequence of the fusion glycoprotein (F) gene of human respiratory syncytial virus (RSV) was constructed and inserted into the thymidine kinase gene of vaccinia virus (WR strain) under the control of a vaccinia virus promoter. The resulting recombinant vaccinia virus, vaccinia F, expressed the F1 and F2 cleavage products (48 and 20 kDa, respectively) of the F glycoprotein in cell culture. F1 and F2 were indistinguishable from their authentic RSV counterparts with respect to glycosylation, disulfide linkage, electrophoretic mobility, cell-surface expression, and antigenic specificity. Cotton rats infected intradermally with vaccinia F developed a high titer of serum F-specific antibodies, which neutralized infectivity of RSV. This neutralizing antibody response exceeded that induced by infection of the respiratory tract with RSV and was 6-fold higher than that induced by vaccinia G, a recombinant vaccinia virus that expressed the RSV G glycoprotein gene. Immunization with vaccinia F stimulated almost complete resistance to replication of RSV in the lower respiratory tract as well as significant resistance in the upper respiratory tract. The degree of resistance conferred by vaccinia F exceeded that induced by vaccinia G.