Identification of the products of the equine herpesvirus type 4 gI and gE genes

Summary.  In order to identify the products of the equine herpesvirus type 4 (EHV-4) gI and gE genes, we have constructed recombinant vaccinia viruses containing the putative gI or gE genes. These recombinant viruses synthesized EHV-4 gI and gE with apparent molecular masses of 75 and 80 kDa, respectively. Antibodies raised against both recombinant viruses detected a 75 kDa gI and a 95 kDa gE in EHV-4-infected cells. The results also suggest that the EHV-4 gI and gE would form a complex like in other herpesviruses. Received October 29, 1999 Accepted January 21, 2000     

Contribution of gene products encoded within the unique short segment of equine herpesvirus 1 to virulence in a murine model

The pathogenesis of three equine herpesvirus 1 (EHV-1) recombinants was assessed in a CBA mouse model. Sequences encoding the majority of glycoproteins I (gI) and E (gE) were deleted from the pathogenic EHV-1 strain RacL11 (L11ΔgIΔgE), and sequences comprising the 3859 bp deletion within the strain KyA U_S segment, which includes genes 73 (gI), 74 (gE), and 75 (putative 10 kDa protein 75), were re-inserted into attenuated KyA (KgI/gE/75). In addition, genes gE and 75 were inserted into KyA to generate the EHV-1 recombinant KgE/75. The insertion of the 3859 bp U_S segment was sufficient to confer virulence to KyA, as indicated by pronounced signs of clinical disease including substantial weight loss. A large plaque morphology was observed in cells infected with KgI/gE/75 compared with KyA, and a small plaque phenotype was observed in cells infected with L11ΔgIΔgE compared with RacL11. These data indicate that gI and/or gI and gE contribute to the ability of EHV-1 to spread directly from cell-to-cell. The deletion of both gI and gE from the pathogenic RacL11 strain did not reduce clinical signs of disease in infected mice, but did decrease mortality compared with RacL11. Furthermore, the insertion of genes 74 (gE) and 75 into the vaccine strain KyA did not alter the attenuated phenotype of this virus. Finally, KgI/gE/75 and RacL11 elicited the production of the proinflammatory chemokines MIP-1, MIP-1β, and MIP-2 in the lungs of infected mice, while KyA did not, suggesting that gI and/or gI and gE contribute to the up-regulation of these mediators of inflammation. These findings show that gI, and/or gI and gE restore a virulent phenotype to the EHV-1 KyA strain, and indicate that virulence factors, in addition to gI and gE, contribute to the pathogenesis of the RacL11 strain.     

Meningoencephalitis in Mice Infected with an Equine Herpesvirus 1 Strain KyA Recombinant Expressing Glycoprotein I and Glycoprotein E

One of the consequences of equine herpesvirus 1 (EHV-1) infection in the natural host is a neurological disease that can lead to paralysis. The pathology associated with EHV-1-induced neurological disease includes vasculitis of the small blood vessels within the central nervous system and subsequent damage to the surrounding neural tissue. In a previous study, an EHV-1 recombinant KyA virus (KgI/gE/75) was generated in which the sequences encoding glycoprotein I (gI) and glycoprotein E (gE) were repaired [Frampton et al. 2002 (Virus Research 90: 287-301)] using genes of the pathogenic EHV-1 strain 89c25. In contrast to the parental KyA virus that lacks gI and gE, the recombinant KgI/gE/75 was able to spread to the brains of CBA mice after intranasal infection. Infection resulted in a meningoencephalitis characterized by lymphocytic cuffing of small blood vessels within the brain, consistent with that observed in EHV-1-infected horses exhibiting neurological signs. KgI/gE/75 was able to elicit cytopathology in the lung prior to spread to the brain. However, like the attenuated KyA strain, KgI/gE/75 did not persist in the lung and was completely cleared from lung tissue by day 5 postinfection. We propose that gI and gE are neurovirulence factors for EHV-1, and that the CBA mouse model can be extended to study neurologic sequelae resulting after EHV-1 infection.     

Glycoproteins gI and gE of Feline Herpesvirus-1 Are Virulence Genes: Safety and Efficacy of a gI–gEDeletion Mutant in the Natural Host

Feline rhinotracheitis virus (FRV) is an important upper respiratory tract pathogen of cats. FRV is a member of the subfamily Alphaherpesvirinae and is designated feline herpesvirus-1 (FHV-1). Besides upper respiratory clinical signs, FHV-1 may cause generalized infections in neonates or abortions in pregnant queens. Recently we described a recombinant FHV-1 strain with a deletion in the genes for glycoproteins gI and gE (FHVβ-galgIgEΔ) and reported that cats vaccinated subcutaneously with high doses of the recombinant FHV-1 strain responded with only mild clinical signs and developed strong immunity against subsequent virulent virus challenge. Here we compare the intranasal and subcutaneous routes of administration of this strain and assess its ability to induce protective immunity and prevent virus shedding after challenge. Cats vaccinated subcutaneously or intranasally with high doses of the recombinant FHV-1 strain responded with only mild clinical signs and developed strong immunity against subsequent virulent virus challenge. This was especially evident when the mutant vaccine was administered oronasally. In contrast, intranasal administration of two other FHV-1 isolates induced severe clinical signs in cats. We conclude from testing this FHV-1 mutant in the natural host that deletion of gE and a portion of gI genes strongly reduces viral virulence but that immunogenicity is maintained.     

Pathogenesis of equine herpesvirus-1 in specific pathogen-free foals: primary and secondary infections and reactivation

Summary Six specific pathogen-free foals shown to be free of equine herpesvirus-1 and 4 (EHV-1 and -4) and lacking in maternally-derived antibodies were used to investigate the pathogenesis of EHV-1 in horses. Following primary intranasal inoculation with EHV-1 all foals showed signs of a mild, self-limiting upper respiratory tract infection. A leucopenia was observed, comprising both a lymphopenia and neutropenia. Virus was isolated from nasal mucus and buffy coat cells over several days during the clinical episode and after the animals became clinically normal. Notwithstanding the mildness of the clinical disease, virus was not eliminated completely and intravenous administration of dexamethasone resulted in reactivation of latent EHV-1 in animals which had received only a single dose of the virus. In a second infection given to four foals, 61 days after the primary inoculation, no clinical signs were observed, haematological changes were minimal and viraemia was absent.     

Characterization of changes in the short unique segment of pseudorabies virus BUK-TK900 (Suivac A) vaccine strain

Summary. Mutant strains of pseudorabies virus (PRV) of reduced virulence, such as Bartha or BUK-TK900, have been used for vaccination purposes for many years. In contrast to the Bartha strain, BUK-TK900 has not been well characterised at the molecular level. The detailed analysis of this vaccine strain was urged by the fact of the isolation in Poland of field strains which were suspected to originate from BUK-TK900.We characterised changes in the U_S region of this strain, focusing our attention on gE and gI genes. The only deletion, about 300bp, found in BamHI 7 fragment (covering most of the U_S region) was located in the 28K (US2) gene. BUK-TK 900 produced small plaques on all cell lines tested in our laboratory (SK6, Vero, MDBK, 3T3). The plaque size was restored to about 70% of wild type virus plaque size when growing BUK-TK900 virus on 3T3 complementing cell line expressing PRV gE and up to 100% when cell line producing gE and gI was used. Both gE and gI genes from BUK-TK900 and from some derivative field isolates have been amplified by PCR reaction but no deletions in these genes have been found. Molecular weight of gene products differed from wild type proteins: gE was bigger than wild type gE while gI was smaller. Both proteins were correctly recognised by all tested polyclonal and monoclonal antibodies. Radioimmunoprecipitation study showed that BUK-TK900 gE and gI interact forming a complex. The whole ORF of BUK-TK900 gE was sequenced and only few point mutations were found; only two of them led to changes of amino acids in the polypeptide chain. These were: methionine at position 124 replaced by threonine and glutamine at position 162 replaced by arginine. The introduction of first of these mutations (Met to Thr) to PRV wild type strain NIA-3 resulted in 22% reduction of plaque size. This result confirms the importance of this domain of gE for its function; it was found previously by others that deletion of amino acids 125 and 126 reduced virulence and neurotropism of PRV. More changes were found in BUK-TK900 gI sequence. Over 80% of these changes were located in the terminal 1/3rd of the sequence. Some of these mutations may have significant effect on the secondary structure of gI glycoprotein. The change of the secondary structure may be responsible for the decrease of gI stability and the observed reduction of gI molecular mass.Present address: Cedi-Diagnostics B.V., Lelystad, The Netherlands.Received May 4, 2001; accepted March 18, 2003 Published online June 11, 2003     

Varicella-Zoster Virus Glycoproteins E and I Expressed in Insect Cells Form a Heterodimer That Requires the N-Terminal Domain of Glycoprotein I

Varicella-zoster virus (VZV) glycoproteins E and I (gE and gI), which are major components of the virion envelope, form a noncovalently linked complex. To understand their properties and functions, we expressed and purified soluble forms of gE and gI in the baculovirus system. Extracellular domains of gE and gI were cloned into baculoviruses, using either native or insect-derived signal peptides. Each recombinant virus yielded soluble protein in culture medium although a higher level of secretion was achieved with insect-derived signal peptides in recombinant gE baculoviruses. A soluble gE–gI complex was formed by co-infecting insect cells with recombinant gE and gI baculoviruses and detected by immunoprecipitation followed by Western blotting analyses. By gel filtration and cross-linking studies, we showed that the VZV gE–gI complex expressed in insect cells is a heterodimer. Interestingly, two recombinant gI proteins in which signal peptides were replaced with insect-derived signal peptides did not associate with gE. Amino-terminal sequencing and site-specific mutational studies showed that the replacement of only the signal peptides did not prevent complex formation but alterations in the processed amino-terminus of gI abrogated its ability to complex with gE. These findings indicate that the mature amino-terminus of gI is required for gE–gI complex formation by the external domains of VZV gE and gI.     

Modulation of the serological response of specific pathogen-free (EHV-free) foals to EHV-1 by previous infection with EHV-4 or a TK-deletion mutant of EHV-1

Summary EHV-1 was inoculated into specific pathogen-free (SPF) foals in order to study uncomplicated primary responses. Infection resulted in a strong serological response recognizing EHV-1-specific antigens; this contrasts with a previous publication where a weak response was recorded in SPF animals. Antibodies to EHV-1 were readily detected by four techniques (virus neutralization, complement fixation, Western blots and immune precipitation), yet there was comparatively little cross-reaction to EHV-4 target antigen. Re-in-oculation with the same virus strain stimulated antibodies to EHV-1 but no additional antigens were recognized and antibodies cross-reacting with EHV-4 antigens were not enhanced. Having characterized the uncomplicated primary response to EHV-1 in SPF foals, further animals were exposed to either EHV-4 or a thymidine kinase-deficient mutant of EHV-1 prior to challenge with w/t EHV-1 to investigate how these infections might modulate the immune responses to EHV-1 or 4. Primary inoculation with EHV-4 or with a thymidine kinase-deficient mutant of EHV-1 produced productive infections as evidenced by virus shedding and pyrexia. In both these cases, however, in contrast to that with w/t EHV-1, the serological response was very weak. Re-infection of foals primed with either EHV-4 or TK-deficient EHV-1 with w/t EHV-1 resulted in a strong response to EHV-1 antigens detected by all four methods. In addition, in the foals given a primary inoculation with EHV-4, superinfection with EHV-1 resulted in a strong cross-reactive response to EHV-4 target antigens. The relevance of these observations to the interpretation of previously reported serological responses to EHVs in SPF and naturally reared animals is discussed.     

The requirement of varicella zoster virus glycoprotein E (gE) for viral replication and effects of glycoprotein I on gE in melanoma cells

The glycoprotein E (gE) of varicella zoster virus (VZV), encoded by ORF68, is the most abundant viral glycoprotein. In the current experiments, we demonstrated that ORF68 deletion was incompatible with recovery of infectious virus from VZV cosmids. Replacing ORF68 at a nonnative AvrII site in the genome restored infectivity. Further, we found that VZV gE could be expressed under the control of the Tet-On promoter in stably transfected melanoma cell lines (Met-gE cells) without evidence of toxicity. In these Met-gE cells, gE colocalized with gamma-adaptin, a trans Golgi network marker, in perinuclear sites, but did not reach plasma membranes. In order to investigate how infection altered gE localization, we made a recombinant virus, vOka-MSPgE, with ORF68 from the VZV MSP strain. VZV MSP encodes a mutant gE protein (D150N) that lacks the mAb epitope, 3B3 (Santos et al., Virology 275, 306-317, 2000), whereas Met-gE protein binds mAb 3B3. Within 48 h after Met-gE cells were infected with vOka-MSPgE, the steady-state distribution of Met-gE protein extended beyond the perinuclear areas to other cytoplasmic sites and to plasma membranes. A second recombinant, vOka-MSPgE without gI (vOka-MSPgEdeltagI), was constructed to investigate Met-gE protein distribution in the absence of gI. The redistribution of Met-gE protein which was observed by 48 h after vOka-MSPgE infection did not occur until 5 days (140 h) within vOka-MSPgEdeltagI infected cells. After vOka-MSPgE infection of Met-gE cells, most Met-gE protein was in the final 94K mature form by 72 h. However, progression to predominance of mature gE was delayed in Met-gE cells infected with vOka-MSPgEdeltagI. These observations confirm our hypothesis that VZV gE is essential, based upon the demonstration of restored infectivity after replacing ORF68 in a nonnative site in the genome, and provide further evidence of the role of gI in facilitating the maturation and intracellular distribution of this critical VZV glycoprotein.     

Biosynthesis and interaction of glycoproteins E and I of canine herpesvirus.

In cells infected with canine herpesvirus (CHV), the mature form of glycoprotein E (gE) had a molecular weight of 94 kDa, and that of glycoprotein I (gI) had a broad range of molecular weights of 55-62 kDa. gE and gI formed a complex like gE and gI of other alphaherpesviruses. When cells were infected with the gI minus mutant of CHV (gI/Z), the mature form of the 94 kDa gE was not formed, but a 76 kDa gE polypeptide was found. Similarly, no mature gI was formed in cells infected with the gE minus mutant of CHV (gE/Z), but a 40 kDa gI polypeptide was formed. When cells were coinfected with gE/Z and gI/Z, the molecular masses of gE and gI were increased from 76 to 94 kDa and from 40 to 55-62 kDa, respectively. We constructed vaccinia virus recombinants which expressed CHV gE or CHV gI. Only when cells were coinfected with both the vaccinia recombinant which expressed gE and the vaccinia recombinant which expressed gI, gE and gI were processed into their mature forms. Our results suggest that the presence of both gE and gI is necessary for efficient processing of the precursors of gE and gI to their mature forms.     

Epitopes on glycoprotein E and on the glycoprotein E/glycoprotein I complex of bovine herpesvirus 1 are expressed by all of 222 isolates and 11 vaccine strains

Summary.  Glycoprotein E (gE) of bovine herpesvirus 1 (BHV1) forms a complex with glycoprotein I (gI) and plays an important role in cell-to-cell spread mechanisms of the virus, but is not essential for propagation of the virus. To study the antigenic variability of BHV1 glycoprotein E, a set of six well characterised monoclonal antibodies (MAbs) was established using BHV1 gE and gI deletion mutants, eukaryotically expressed gE and gI and pepscan analysis. Two of these MAbs reacted with a linear gE epitope (MAbs 3 and 52), two reacted with a more conformation dependent gE epitope (MAbs 61 and 81) and two reacted with epitopes formed by a complex formed between gE and glycoprotein I (MAbs 67 and 75). With these six MAbs the gE expression of 222 BHV1 isolates and 11 BHV1 modified-live vaccine strains was studied in vitro, using an immunoperoxidase monolayer assay. All 222 BHV1 isolates and 11 vaccine strains were found to react with MAbs 61, 81 and 75. Three of the 222 isolates failed to react with MAb 67 and two of the vaccines reacted very weakly with MAbs 3 and 52. Analysis of the gE genes of these five aberrant isolates and the gE glycoproteins they expressed, did not show obvious size differences compared to wild-type BHV1. We conclude that the tested gE epitopes are highly conserved, including the epitopes formed by the gI/gE complex. Received September 15, 1999/Accepted December 16, 1999     

A comparative study of pseudorabies virus (PRV) strains with defects in thymidine kinase and glycoprotein genes

In the course of two experiments, an examination was made of the virulence and neuroinvasiveness for pigs of two pseudorabies virus mutants (strain 6C2TK(-), with a defect in thymidine kinase (TK) function; and strain 6C2TK(-), gI(-)/gE(-), with defects in TK and glycoproteins I and E) and of the wild-type parent strain (86/27V). At various times after intranasal inoculation, pigs were killed and samples of tonsil, lung and different levels of the trigeminal and olfactory nervous pathways were examined by methods that included viral isolation, polymerase chain reaction assay and immunohistochemistry. Both mutant viruses were of reduced virulence, as indicated by no more than moderate clinical signs and lesions, and only sporadic isolation of virus; moreover, unlike the wild-type parent strain, the mutant viruses were not reactivated from the latent state by corticosteroid treatment. In addition, migration of the mutant strains to the central nervous system (olfactory and trigeminal nervous pathways) was reduced as compared with that of the wild-type strain. Thus, mutations in the genes encoding the TK enzyme and the gI/gE complex were associated with reduced virulence, reduced replication in peripheral target tissues, and reduced migration to the olfactory and trigeminal pathways.     

A glycoprotein I- and glycoprotein E-deficient mutant of infectious laryngotracheitis virus exhibits impaired cell-to-cell spread in cultured cells

Summary. In alphaherpesviruses, glycoprotein I (gI) and glycoprotein E (gE) form a heterodimer that functions in cell-to-cell spread of the virus. Generally, alphaherpesvirus mutants that lack these glycoproteins are replication competent in cell culture but show a reduced capacity for cell-to-cell spread and hence smaller plaque sizes. Infectious laryngotracheitis virus (ILTV), or Gallid herpesvirus 1, is an alphaherpesvirus that causes respiratory disease in chickens. The roles of gI and gE in ILTV have not been investigated previously. In this study, a glycoprotein I and glycoprotein E deletion mutant of ILTV (gI/gE-ve ILTV) was generated by replacing the region of the ILTV genome coding for the adjacent gI and gE genes with the gene for enhanced green fluorescent protein (eGFP). This gI/E-ve ILTV was readily propagated in cell culture in the presence of wildtype ILTV (wt ILTV). However, in the absence of wt ILTV the propagation of gI/gE-ve ILTV was severely impaired. Infection of permissive cell cultures with gI/gE-ve ILTV failed to produce plaques but single infected cells could be identified by fluorescence microscopy. This suggests that gI/gE has a more significant role in the cell-to-cell spread of ILTV in vitro than in many other alphaherpesviruses.     

Glycoprotein E (gE) specified by bovine herpesvirus type 5 (BHV-5) enables trans-neuronal virus spread and neurovirulence without being a structural component of enveloped virions

Bovine herpesvirus 5 (BHV-5) is a neurovirulent alpha-herpesvirus that causes fatal encephalitis in calves. We previously demonstrated that deletion of a glycine-rich epitope in the gE ectodomain dramatically reduced BHV-5 neurovirulence. To investigate the role of gE cytoplasmic tail sequences in the neuropathogenesis of BHV-5 in rabbits, we constructed a BHV-5gE recombinant virus with a short residual cytoplasmic domain lacking the YXXL motifs and the acidic (BHV-5gEAm480). In vitro, BHV-5gEAm480 produced on the average smaller plaques, compared with wild-type BHV-5, but it produced on the average substantially larger plaques than the gE ORF-deleted BHV-5. The truncated gE was not phosphorylated, and was not endocytosed from the cell surface. Importantly, the truncated gE was not incorporated into enveloped infectious virions, but its glycosylation and interaction with gI were not affected. In a rabbit model of infection, the BHV-5gEAm480 remained highly virulent, while the gE-null virus was avirulent. The gEAm480 mutant virus invaded most of the central nervous system (CNS) structures that are invaded by the wild-type BHV-5. The number of neurons infected by BHV-5gEAm480 was very similar to the number infected by BHV-5 wild-type and gEAm480-rescued viruses. Collectively, the results suggest that gE functions in transsynaptic transmission of BHV-5 and neurovirulence without being a structural component of the virion particle.     

In vitro and in vivo characterization of equine herpesvirus type 1 (EHV-1) mutants devoid of the viral chemokine-binding glycoprotein G (gG)

Glycoprotein G (gG) of equine herpesvirus type 1 (EHV-1), a structural component of virions and secreted from virus-infected cells, was shown to bind to a variety of different chemokines and as such might be involved in immune modulation. Little is known, however, about its role in the replication cycle and infection of EHV-1 in vivo. Here we report on the function of gG in context of virus infection in vitro and in vivo. A gG deletion mutant of pathogenic EHV-1 strain RacL11 (vL11DeltagG) was constructed and analyzed. Deletion of gG had virtually no effect on the growth properties of vL11DeltagG in cell culture when compared to parental virus or a rescuant virus vL11DeltagGR, respectively, and virus titers and plaque formation were unaffected in the absence of the glycoprotein. Similarly, in the murine model of EHV-1 infection, no significant differences in virulence between the gG deletion mutant and RacL11 or vL11DeltagGR were found at high doses of infection. However, infection of mice at lower doses revealed that the gG deletion mutant was able to replicate to higher titers in lungs of infected mice. Additionally, these mice lost significantly more weight than those infected with RacL11 and a more pronounced inflammatory response in lungs was observed. Therefore we concluded that deletion of gG in EHV-1 seems to lead to an exacerbation of respiratory disease in the mouse.     

Herpes simplex virus IgG Fc receptors induced using recombinant adenovirus vectors expressing glycoproteins E and I

Evidence has been presented that herpes simplex virus (HSV) immunoglobulin (IgG) Fc receptors are composed of a complex of two glycoproteins, gE and gI. In previous studies, cells infected with HSV-1 mutants lacking either gE or gI bound lower levels of soluble IgG than cells infected with wild-type viruses suggesting that both gE and gI were required for IgG binding. We have reevaluated the Fc receptor activity of these mutants using a more sensitive assay involving IgG-coated erythrocytes and have found that cells infected with a gE- mutant HSV-1 did not bind IgG-coated erythrocytes whereas cells infected with a gI- mutant retained some Fc binding activity. To further study HSV-induced Fc receptors recombinant adenovirus vectors expressing gE or gI were constructed. Cells expressing gE alone bound both soluble IgG and IgG-coated red cells, although the binding was consistently lower than that observed with HSV-infected cells or cells expressing both gE and gI. Cells expressing only gI were unable to bind either soluble IgG or IgG-coated erythrocytes. These results support the conclusion that both gE and gI are required for full Fc receptor activity, although gE alone can bind IgG to a lesser extent.     

Spontaneous BHV1 recombinants in which the gI/gE/US9 region is replaced by a duplication/inversion of the US1.5/US2 region

Summary.  In a bovine herpesvirus 1 (BHV1) vaccine strain, a spontaneous BHV1 mutant (Za) was found that arose from a recombination between two isomeric forms of the BHV1 genome. In this Za mutant one end of the U_S region, containing part of the US1.5 gene, was found duplicated in an inverted orientation at the other end of the U_S region. Concurrently, a 2.7 kb deletion was found in Za that encompasses both the US8 (gE) and US9 gene. Analysis of the in vitro growth properties of a genetically modified BHV1gE⁻ mutant showed that at 11 hours post infection BHV1gE⁻ viruses were secreted ten times more efficiently than wild type virus. Using this observation we developed a protocol to enrich for spontaneous gE deletion mutants in a BHV1 field isolate and found another mutant (Rof3) with similar properties as the Za mutant. Rof3 has a duplication/inversion of the US1.5 gene and part of the US2 gene and a simultaneous 3.5 kb deletion that encompasses the US7 (gI), US8 (gE) and US9 genes. The nucleotide sequences of the recombination points of both recombinants were determined and compared. No obvious sequence similarities were found, suggesting that non-homologous recombination events led to the observed recombinations. The implications for the use of BHV1 gE deletion mutants as marker or diva vaccines are discussed. Received January 10, 1999 Accepted March 29, 1999     

Formation of Pseudorabies virus glycoprotein E/I complex in baculovirus recombinant system

Glycoproteins E (gE) and I (gI) of Pseudorabies virus (PRV) form a non-covalently bound complex to which a number of functions have been attributed. The gE/gI complex formation was studied using a series of full-length and truncated forms of gE and gI expressed in baculovirus recombinant system. Both glycoproteins were truncated by stepwise removal of their C-terminal parts and their ability to form the complex was studied by radioimmunoprecipitation. It was found that N-terminal domains of gE and gI containing first 122 and 106 aa, respectively, were sufficient for the complex formation.