The transmembrane and cytosolic domains of equine herpesvirus type 1 glycoprotein D determine Golgi retention by regulating vesicle formation

Accumulating evidence underscores the pivotal role of envelope proteins in viral secondary envelopment. However, the intricate molecular mechanisms governing this phenomenon remain elusive. To shed light on these mechanisms, we investigated a Golgi-retained gD of EHV-1 (gDEHV-1), distinguishing it from its counterparts in Herpes Simplex Virus-1 (HSV-1) and Pseudorabies Virus (PRV). To unravel the specific sequences responsible for the Golgi retention phenotype, we employed a gene truncation and replacement strategy. The results suggested that Golgi retention signals in gDEHV-1 exhibiting a multi-domain character. The extracellular domain of gDEHV-1 was identified as an endoplasmic reticulum (ER)-resident domain, the transmembrane domain and cytoplasmic tail (TM-CT) of gDEHV-1 were integral in facilitating the protein's residence within the Golgi complex. Deletion or replacement of either of these dual domains consistently resulted in the mutant gDEHV-1 being retained in an ER-like structure. Moreover, (TM-CT)EHV-1 demonstrated a preference for binding to endomembranes, inducing the generation of a substantial number of vesicles, potentially originate from the Golgi complex or the ER-Golgi intermediate compartment. In conclusion, our findings provide insights into the intricate molecular mechanisms governing the Golgi retention of gDEHV-1, facilitating the comprehension of the processes underlying viral secondary envelopment.

[Impact of fluorescent protein tag on gD envelope protein subcellular localization in BHK-21 cells]

OBJECTIVE

The fluorescent protein and gD envelope protein of equine herpes virus type 1 (EHV-1) were used to study the impact of tags on gD protein subcellular localization in BHK-21 cells.

METHODS

With the EHV-1 genome as a template, the gD complete gene was amplified by PCR technique. The product of PCR was cloned to pAcGFP1-C1 and pDsRed2-N1 plasmids. The recombinant plasmids were designated as pAc-GFP-gD (GFP-gD) and pDs-gD-Red (gD-Red). The GFP gene was inserted into the posterior position of gD gene signal peptide sequence. The modified gD gene signal peptide sequence was cloned to pVAX-1 plasmid, so that pVAX-S-GFP-gD' (S-GFPgD') recombinant plasmid was constructed. Meanwhile, the flag tag was added to N-terminal of gD sequence and they were cloned to pVAX-1 expression vector for constructing pVAX-Flag-gD recombinant plasmid. The BHK-21 cells were transfected with the 4 different recombinant plasmids and the subcellular localizations of fusion proteins were determined by lasar confocal scan microscopy.

RESULTS

Four eukaryotic expression vectors were constructed successfully. In BHK-21 cells, the vast majority of gD envelope proteins was localized in Golgi, and a small amount of gD was localized in the nucleus.

CONCLUSION

Our finding reveals that the fluorescent protein of different insertion sites has no significant effects on the subcellular localization of gD, and provides a useful reference for other researchers.

[DIFFERENTIAL SENSITIVITY OF MICROORGANISMS TO POLYHEXAMETHYLENEGUANIDINE]

Factors identified that affect the sensitivity of microorganisms to polyhexamethyleneguanidine (PHMG). Salts of PHMG chloride, valerate, maleate, succinate was to use. Test strains of Esherichia coli, Staphylococcus aureus, Bacillus cereus, Leptospira interrogans, Paenibacillus larvae, Mycobacterium bovis, M. avium, M. fortuitum, Aspergillus niger and some strains of viruses are taken as objects of research. We have determined that the cytoplasm membrane phospholipids is main "target" for the polycation molecules of PHMG. A differential sensitivity of the microorganisms to this drug is primarily determined by relative amount of lipids in membrane and their accessibility. Such trends exist: increase the relative contents of anionic lipids and more negative surface electric potential of membrane, and reduction of the sizes fat acid remainder of lipids bring to increase of microorganism sensitivity. Types of anion salt PHMG just have a certain value. Biocide activity of PHMG chloride is more, than its salts with organic acid. Feasibility of combining PHMG with other biocides in the multicomponent disinfectants studied and analyzed. This combination does not lead to a significant increase in the sensitivity of microorganisms tested in most cases. Most species of pathogenic bacteria can be quickly neutralized by aqueous solutions of PHMG in less than 1% concentrations.

Equid herpesvirus type 1 activates platelets

Equid herpesvirus type 1 (EHV-1) causes outbreaks of abortion and neurological disease in horses. One of the main causes of these clinical syndromes is thrombosis in placental and spinal cord vessels, however the mechanism for thrombus formation is unknown. Platelets form part of the thrombus and amplify and propagate thrombin generation. Here, we tested the hypothesis that EHV-1 activates platelets. We found that two EHV-1 strains, RacL11 and Ab4 at 0.5 or higher plaque forming unit/cell, activate platelets within 10 minutes, causing α-granule secretion (surface P-selectin expression) and platelet microvesiculation (increased small events double positive for CD41 and Annexin V). Microvesiculation was more pronounced with the RacL11 strain. Virus-induced P-selectin expression required plasma and 1.0 mM exogenous calcium. P-selectin expression was abolished and microvesiculation was significantly reduced in factor VII- or X-deficient human plasma. Both P-selectin expression and microvesiculation were re-established in factor VII-deficient human plasma with added purified human factor VIIa (1 nM). A glycoprotein C-deficient mutant of the Ab4 strain activated platelets as effectively as non-mutated Ab4. P-selectin expression was abolished and microvesiculation was significantly reduced by preincubation of virus with a goat polyclonal anti-rabbit tissue factor antibody. Infectious virus could be retrieved from washed EHV-1-exposed platelets, suggesting a direct platelet-virus interaction. Our results indicate that EHV-1 activates equine platelets and that α-granule secretion is a consequence of virus-associated tissue factor triggering factor X activation and thrombin generation. Microvesiculation was only partly tissue factor and thrombin-dependent, suggesting the virus causes microvesiculation through other mechanisms, potentially through direct binding. These findings suggest that EHV-1-induced platelet activation could contribute to the thrombosis that occurs in clinically infected horses and provides a new mechanism by which viruses activate hemostasis.

The equine herpesvirus-1 IR3 gene that lies antisense to the sole immediate-early (IE) gene is trans-activated by the IE protein, and is poorly expressed to a protein

The unique IR3 gene of equine herpesvirus 1 (EHV-1) is expressed as a late 1.0-kb transcript. Previous studies confirmed the IR3 transcription initiation site and tentatively identified other cis-acting elements specific to IR3 such as a TATA box, a 443 base pair 5'untranslated region (UTR), a 285 base pair open reading frame (ORF), and a poly adenylation (A) signal [Holden, V.R., Harty, R.N., Yalamanchili, R.R., O'Callaghan, D.J., 1992. The IR3 gene of equine herpesvirus type 1: a unique gene regulated by sequences within the intron of the immediate-early gene. DNA Seq. 3, 143-152]. Transient transfection assays revealed that the IR3 promoter is strongly trans-activated by the IE protein (IEP) and that coexpression of the IEP with the early EICP0 and IR4 regulatory proteins results in maximal trans-activation of the IR3 promoter. Gel shift assays revealed that the IEP directly binds to the IR3 promoter region. Western blot analysis showed that the IR3 protein produced in E. coli was detected by antibodies to IR3 synthetic peptides; however, the IR3 protein was not detected in EHV-1 infected cell extracts by these same anti-IR3 antibodies, even though the IR3 transcript was detected by northern blot. These findings suggest that the IR3 may not be expressed to a protein. Expression of an IR3/GFP fusion gene was not observed, but expression of a GFP/IR3 fusion gene was detected by fluorescent microscopy. In further attempts to detect the IR3/GFP fusion protein using anti-GFP antibody, western blot analysis showed that the IR3/GFP fusion protein was not detected in vivo. Interestingly, a truncated form of the GFP/IR3 protein was synthesized from the GFP/IR3 fusion gene. However, GFP/IR3 and IR3/GFP fusion proteins of the predicted sizes were synthesized by in vitro coupled transcription and translation of the fusion genes, suggesting poor expression of the IR3 protein in vivo. The possible role of the IR3 transcript in EHV-1 infection is discussed.

Genetic Complexity of EHV-1 Defective Interfering Particles and Identification of Novel IR4/UL5 Hybrid Proteins Produced During Persistent Infection

This study examined the genetic complexity of three equine herpesvirus 1 (EHV-1) defective interfering particles (DIP) and found the DIP genomes to range from 5.9 kbp to 7.3 kbp in total size. Each DIP contains an identical 5' end ( approximately 1.9 kb) that harbors UL3 and UL4 genes that are 100% identical to those of the infectious virus. DIP2 and DIP3 contain a previously described unique IR4/UL5 (EICP22/EICP27) hybrid gene (Hyb1.0). The DIP1 genome, however, appears to be generated from a different recombination event which results in the formation of a new distinct hybrid ORF. The new ORF (Hyb2.0) is comprised of 684 bp from the 5' end of IR4 fused to 45 bp from the 3' terminus of UL5. In contrast to Hyb1.0, the UL5 sequences present in Hyb2.0 are not in-frame. Thus, the Hyb2.0 protein is comprised of 228 residues from IR4 linked to a sequence of 15 amino acids that result from a frameshifted reading of UL5 sequences. Western blot analysis confirmed that the Hyb2.0 ORF is expressed during persistent infection to produce a family of proteins that migrate at 36-42 kDa. Fluorescence microscopy revealed that both Hyb proteins display diffuse cytoplasmic localization patterns dissimilar to the nuclear localization patterns of both IR4 and UL5. Neither Hyb protein, however, disrupts the nuclear entry of the EHV-1 immediate-early, IR4, or UL5 proteins or cellular TATA box binding protein (TBP) previously shown to interact with both IR4 or UL5 in productive infection. DIP genomic segments ( approximately 3.5-5.0 kbp) downstream of the 100% conserved origin of replication are highly variable among the three DIP genomes and contain large areas of repetitive sequences. The possibility that the non-coding sequences play a role in viral interference and/or persistent infection remains to be determined.

Differential susceptibility of equine and mouse brain microvascular endothelial cells to equine herpesvirus 1 infection

Equine herpesvirus 1 (EHV-1) shows endotheliotropism in the central nervous system (CNS) of infected horses. However, infection of endothelial cells has not been observed in the CNS of infected mice. To explore the basis for this difference in endotheliotropism, we compared the susceptibility of equine brain microvascular endothelial cells (EBMECs) and mouse brain microvascular endothelial cells (MBMECs) to EHV-1 infection. The kinetics of viral growth in EBMECs was typical of a fully productive infection whereas viral infection in MBMECs seemed to be nonproductive. Immunofluorescence microscopy using anti-EHV-1 polyclonal antibody demonstrated viral antigen in infected EBMECs, but not infected MBMECs. EHV-1 immediate early (IE), early (ICP0), and late (gB, gD and gK) transcripts were expressed in infected EBMECs. However, none of these genes was detected in infected MBMECs by reverse transcription-polymerase chain reaction. Electron microscopic examination at the stage of viral entry showed that viral particles were present within uncoated vesicles in the cytoplasm of EBMECs, but absent from those of MBMECs. These results suggest that viral entry is an important determinant of the susceptibility of EBMECs and MBMECs to EHV-1 infection.

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.

The equine herpesvirus 1 EICP27 protein enhances gene expression via an interaction with TATA box-binding protein

The mechanism(s) by which the early EICP27 gene product cooperates with other equine herpesvirus 1 (EHV-1) regulatory proteins to achieve maximal promoter activity remains unknown. Transient transfection assays revealed that deletion of residues 93-140 of the 470-aa EICP27 protein substantially diminished its activation of the immediate-early (IE) promoter, whereas deletion of residues 140-470 that contain a zinc-finger motif abolished this activity. Fluorescence microscopy of cells expressing the full-length EICP27 protein or portions of this protein revealed that an arginine-rich sequence spanning residues 178-185 mediates nuclear entry. Experiments employing the mammalian Gal4 two-plasmid system revealed that the EICP27 protein does not possess an independent trans-activation domain (TAD). Protein-protein interaction assays using purified proteins revealed that residues 124-220 of the EICP27 protein mediate its direct interaction with TATA box-binding protein (TBP). Partial deletion of this TBP-binding domain attenuated the ability of the EICP27 protein to stimulate the IE and early EICP0 promoters by 68% and 71%, respectively, indicating the importance of this protein-protein interaction.

Peptide transport activity of the transporter associated with antigen processing (TAP) is inhibited by an early protein of equine herpesvirus-1

Equine herpesvirus-1 (EHV-1) downregulates surface expression of major histocompatibility complex (MHC) class I molecules on infected cells. The objective of this study was to investigate whether EHV-1 interferes with peptide translocation by the transporter associated with antigen processing (TAP) and to identify the proteins responsible. Using an in vitro transport assay, we showed that EHV-1 inhibited transport of peptides by TAP as early as 2 h post-infection (p.i). Complete shutdown of peptide transport was observed by 8 h p.i. Furthermore, pulse–chase experiments revealed that maturation of class I molecules in the endoplasmic reticulum (ER) was delayed in EHV-1-infected cells, which may be due to reduced availability of peptides in the ER as a result of TAP inhibition. Metabolic inhibition studies indicated that an early protein(s) of EHV-1 is responsible for this effect.

Generation and characterization of an EICP0 null mutant of equine herpesvirus 1

The EICP0 gene (gene 63) of equine herpesvirus 1 (EHV-1) encodes an early regulatory protein that is a promiscuous trans-activator of all classes of viral genes. Bacterial artificial chromosome (BAC) technology and RecE/T cloning were employed to delete the EICP0 gene from EHV-1 strain KyA. Polymerase chain reaction, Southern blot analysis, and DNA sequencing confirmed the deletion of the EICP0 gene and its replacement with a kanamycin resistance gene in mutant KyA. Transfection of rabbit kidney cells with the EICP0 mutant genome produced infectious virus, indicating that the EICP0 gene is not essential for KyA replication in cell culture. Experiments to assess the effect of the EICP0 deletion on EHV-1 gene programming revealed that mRNA expression of the immediate-early gene and representative early and late genes as well as the synthesis of these viral proteins were reduced as compared to the kinetics of viral mRNA and protein synthesis observed for the wild type virus. However, the transition from early to late viral gene expression was not prevented or delayed, suggesting that the absence of the EICP0 gene did not disrupt the temporal aspects of EHV-1 gene regulation. The extracellular virus titer and plaque areas of the EICP0 mutant virus KyADeltaEICP0, in which the gp2-encoding gene 71 gene that is absent in the KyA BAC was restored, were reduced by 10-fold and 19%, respectively, when compared to parental KyA virus; while the titer and plaque areas of mutant KyADeltaEICP0Deltagp2 that lacks both the EICP0 gene and gene 71 were reduced more than 50-fold and 67%, respectively. The above results show that the EICP0 gene is dispensable for EHV-1 replication in cell culture, and that the switch from early to late viral gene expression for the representative genes examined does not require the EICP0 protein, but that the EICP0 protein may be structurally required for virus egress and cell-to-cell spread.

The equine herpesvirus 1 UL11 gene product localizes to the trans-golgi network and is involved in cell-to-cell spread

Experiments were conducted to identify and characterize the equine herpesvirus type 1 (EHV-1) UL11 homologous protein. At early-late times after EHV-1 infection of Rk13 cells several proteins at an M(r) of 8000 to 12,000 were detected using a UL11 protein-specific antiserum. Particularly, an M(r) of 11,000 protein was found abundantly in purified virions and could be assigned to the tegument fraction. As demonstrated by confocal laser scanning microscopy, UL11 reactivity localized predominantly to the trans-Golgi network of infected cells, but was also noted at the plasma membrane, specifically of transfected cells. Deletion of UL11 sequences in EHV-1 vaccine strain RacH (Hdelta11) and in the virulent isolate RacL22 (Ldelta11) resulted in viruses that were able to replicate on noncomplementing cells. It was shown in one-step growth kinetics on Rk13 cells that the reduction of intracellular and of extracellular virus titers caused by the absence of UL11 expression in either virus was somewhat variable, but approximately 10- to 20-fold. In contrast, a marked influence on the plaque phenotype was noted, as mean maximal diameters of plaques were reduced to 23.2% (RacL22) or 34.7% (RacH) of parental virus plaques and as an effect on the ability of RacH to cause syncytia upon infection was noted. It was therefore concluded that the EHV-1 UL11 product is not essential for virus replication in Rk13 cells but is involved in cell-to-cell spread.

Glycoprotein G isoforms from some alphaherpesviruses function as broad-spectrum chemokine binding proteins

Mimicry of host chemokines and chemokine receptors to modulate chemokine activity is a strategy encoded by beta- and gammaherpesviruses, but very limited information is available on the anti-chemokine strategies encoded by alphaherpesviruses. The secretion of chemokine binding proteins (vCKBPs) has hitherto been considered a unique strategy encoded by poxviruses and gammaherpesviruses. We describe a family of novel vCKBPs in equine herpesvirus 1, bovine herpesvirus 1 and 5, and related alphaherpesviruses with no sequence similarity to chemokine receptors or other vCKBPs. We show that glycoprotein G (gG) is secreted from infected cells, binds a broad range of chemokines with high affinity and blocks chemokine activity by preventing their interaction with specific receptors. Moreover, gG also blocks chemokine binding to glycosaminoglycans, an interaction required for the correct presentation and function of chemokines in vivo. In contrast to other vCKBPs, gG may also be membrane anchored and, consistently, we show chemokine binding activity at the surface of cells expressing full-length protein. These alphaherpesvirus vCKBPs represent a novel family of proteins that bind chemokines both at the membrane and in solution.

Interaction of the equine herpesvirus 1 EICP0 protein with the immediate-early (IE) protein, TFIIB, and TBP may mediate the antagonism between the IE and EICP0 proteins

The equine herpesvirus 1 (EHV-1) immediate-early (IE) and EICP0 proteins are potent trans-activators of EHV-1 promoters; however, in transient-transfection assays, the IE protein inhibits the trans-activation function of the EICP0 protein. Assays with IE mutant proteins revealed that its DNA-binding domain, TFIIB-binding domain, and nuclear localization signal may be important for the antagonism between the IE and EICP0 proteins. In vitro interaction assays with the purified IE and EICP0 proteins indicated that these proteins interact directly. At late times postinfection, the IE and EICP0 proteins colocalized in the nuclei of infected equine cells. Transient-transfection assays showed that the EICP0 protein trans-activated EHV-1 promoters harboring only a minimal promoter region (TATA box and cap site), suggesting that the EICP0 protein trans-activates EHV-1 promoters by interactions with general transcription factor(s). In vitro interaction assays revealed that the EICP0 protein interacted directly with the basal transcription factors TFIIB and TBP and that the EICP0 protein (amino acids [aa] 143 to 278) mediated the interaction with aa 125 to 174 of TFIIB. Our unpublished data showed that the IE protein interacts with the same domain (aa 125 to 174) of TFIIB and with TBP. Taken together, these results suggested that interaction of the EICP0 protein with the IE protein, TFIIB, and TBP may mediate the antagonism between the IE and EICP0 proteins.

Egress of alphaherpesviruses: comparative ultrastructural study

Egress of four important alphaherpesviruses, equine herpesvirus 1 (EHV-1), herpes simplex virus type 1 (HSV-1), infectious laryngotracheitis virus (ILTV), and pseudorabies virus (PrV), was investigated by electron microscopy of infected cell lines of different origins. In all virus-cell systems analyzed, similar observations were made concerning the different stages of virion morphogenesis. After intranuclear assembly, nucleocapsids bud at the inner leaflet of the nuclear membrane, resulting in enveloped particles in the perinuclear space that contain a sharply bordered rim of tegument and a smooth envelope surface. Egress from the perinuclear cisterna primarily occurs by fusion of the primary envelope with the outer leaflet of the nuclear membrane, which has been visualized for HSV-1 and EHV-1 for the first time. The resulting intracytoplasmic naked nucleocapsids are enveloped at membranes of the trans-Golgi network (TGN), as shown by immunogold labeling with a TGN-specific antiserum. Virions containing their final envelope differ in morphology from particles within the perinuclear cisterna by visible surface projections and a diffuse tegument. Particularly striking was the addition of a large amount of tegument material to ILTV capsids in the cytoplasm. Extracellular virions were morphologically identical to virions within Golgi-derived vesicles, but distinct from virions in the perinuclear space. Studies with gB- and gH-deleted PrV mutants indicated that these two glycoproteins, which are essential for virus entry and direct cell-to-cell spread, are dispensable for egress. Taken together, our studies indicate that the deenvelopment-reenvelopment process of herpesvirus maturation also occurs in EHV-1, HSV-1, and ILTV and that membrane fusion processes occurring during egress are substantially different from those during entry and direct viral cell-to-cell spread.

EHV-1 glycoprotein D (EHV-1 gD) is required for virus entry and cell-cell fusion, and an EHV-1 gD deletion mutant induces a protective immune response in mice

Insertional mutagenesis was used to construct an equine herpesvirus 1 (EHV-1) mutant in which the open reading frame for glycoprotein D was replaced by a lacZ cassette. This gD deletion mutant (delta gD EHV-1) was unable to infect normally permissive RK cells in culture, but could be propagated in an EHV-1 gD-expressing cell line (RK/gD). Phenotypically complemented delta gD EHV-1 was able to infect RK cells, but did not spread to form syncytial plaques as seen with wild type EHV-1 or with delta gD EHV-1 infection of RK/gD cell cultures. Therefore EHV-1 gD is required for virus entry and for cell-cell fusion. The phenotypically complemented delta gD EHV-1 had very low pathogenicity in a mouse model of EHV-1 respiratory disease, compared to a fully replication-competent EHV-1 reporter virus (lacZ62/63 EHV-1). Intranasal or intramuscular inoculation of mice with delta gD EHV-1 induced protective immune responses that were similar to those elicited in mice inoculated with lacZ62/63 EHV-1 and greater than those following inoculation with UV-inactivated virus.

The equine herpesvirus 1 UL45 homolog encodes a glycosylated type II transmembrane protein and is involved in virus egress

Experiments to analyze the product of the equine herpesvirus type 1 (EHV-1) UL45 homolog were conducted. Using an antiserum generated against the carboxylterminal 114 amino acids of the EHV-1 UL45 protein, proteins of M(r) 32,000, 40,000, and 43,000 were detected specifically in EHV-1-infected cells. Neither form of the protein was located in purified virions of EHV-1 wild-type strain RacL22 or the modified live vaccine strain RacH, but UL45 was demonstrated to be expressed as a late (gamma-2) protein. Fractionation of infected cells and deglycosylation experiments demonstrated that the EHV-1 UL45 protein represents a type II membrane glycoprotein. Deletion of the UL45 gene in RacL22 and RacH (LDelta45 and HDelta45) showed that UL45 is nonessential for EHV-1 growth in vitro, but that deletion reduced the viruses' replication efficiency. A marked reduction of virus release was observed although no significant influence was noticed either on plaque size or on the syncytial phenotype of the EHV-1 strain RacH.

The equine herpesvirus 1 immediate-early protein interacts with EAP, a nucleolar-ribosomal protein

The equine herpesvirus 1 (EHV-1) immediate-early (IE) phosphoprotein is essential for the activation of transcription from viral early and late promoters and regulates transcription from its own promoter. The IE protein of 1487 amino acids contains a serine-rich tract (SRT) between residues 181 and 220. Deletion of the SRT decreased transactivation activity of the IE protein. Previous results from investigation of the ICP4 protein, the IE homolog of herpes simplex virus 1 (HSV-1), revealed that a domain containing a serine-rich tract interacts with EAP (Epstein-Barr virus-encoded small nuclear RNA-associated protein), a 15-kDa nucleolar-ribosomal protein (R. Leopardi, and B. Roizman, Proc. Natl. Acad. Sci. USA 93, 4572-4576, 1996). DNA binding assays revealed that (i) glutathione S-transferase (GST)-EAP disrupted the binding of HSV-1 ICP4 to its cognate DNA in a dose-dependent manner, (ii) GST-EAP interacted with the EHV-1 IE protein, but did not disrupt its binding to its cognate site in viral DNA. GST-pulldown assays indicated that the SRT of the IE protein is required for physical interaction with EAP. The IE protein and EAP colocalized in the cytoplasm of the infected equine ETCC cells at late times of the infection cycle. This latter finding may be important in EHV-1 gene regulation since late viral gene expression is greatly influenced by the EICP0 trans-activator protein whose function is antagonized by the IE protein.

Differences in determinants required for complex formation and transactivation in related VP16 proteins

VP16-H is an essential structural protein of herpes simplex virus type 1 (HSV-1) and is also a potent activator of virus immediate-early (IE) gene expression. Current models of functional determinants within VP16-H indicate that it consists of two domains, an N-terminal domain involved in recruiting VP16-H to a multicomponent DNA binding complex with two host proteins, Oct-1 and host cell factor (HCF), and an acidic C-terminal domain exclusively involved in transactivation. VP16-E, from equine herpesvirus 1 (EHV-1), exhibits strong conservation with the N-terminal domain of VP16-H but, with the exception of a short segment at the extreme C terminus, lacks almost the entire acidic C-terminal domain. Studies of key activation determinants within the C terminus of VP16-H would predict that VP16-E may activate poorly, if at all. However, VP16-E is a potent activator of both EHV-1 and HSV-1 IE gene transcription. We show that VP16-E does not follow the simple two-domain model of VP16-H. Thus, despite the conservation in the N-terminal domains, this region in VP16-E is not sufficient for assembly into the DNA binding complex with Oct-1 and HCF. The short conserved determinant close to the C terminus is completely dispensable in VP16-H but is absolutely required in VP16-E. In activation studies, the potency of intact VP16-E was not recapitulated in chimeric proteins in which it was fused with a GAL4 DNA binding domain. Furthermore, a chimeric protein consisting of the C-terminal region of VP16-E fused to the N-terminal domain of VP16-H, while able to promote complex formation, nevertheless exhibited very weak activation. These results indicate that the mode of recruitment of the activation domain, i.e., through complex formation with Oct-1 and HCF, may be crucial for activation and that key determinants required for activation in VP16-E, and possibly VP16-H, may involve interactions between regions of the C terminus and the N terminus rather than discrete domains with independent functions.

Pseudorabies virus glycoprotein M inhibits membrane fusion

A transient transfection-fusion assay was established to investigate membrane fusion mediated by pseudorabies virus (PrV) glycoproteins. Plasmids expressing PrV glycoproteins under control of the immediate-early 1 promoter-enhancer of human cytomegalovirus were transfected into rabbit kidney cells, and the extent of cell fusion was quantitated 27 to 42 h after transfection. Cotransfection of plasmids encoding PrV glycoproteins B (gB), gD, gH, and gL resulted in formation of polykaryocytes, as has been shown for homologous proteins of herpes simplex virus type 1 (HSV-1) (A. Turner, B. Bruun, T. Minson, and H. Browne, J. Virol. 72:873-875, 1998). However, in contrast to HSV-1, fusion was also observed when the gD-encoding plasmid was omitted, which indicates that PrV gB, gH, and gL are sufficient to mediate fusion. Fusogenic activity was enhanced when a carboxy-terminally truncated version of gB (gB-008) lacking the C-terminal 29 amino acids was used instead of wild-type gB. With gB-008, only gH was required in addition for fusion. A very rapid and extended fusion was observed after cotransfection of plasmids encoding gB-008 and gDH, a hybrid protein consisting of the N-terminal 271 amino acids of gD fused to the 590 C-terminal amino acids of gH. This protein has been shown to substitute for gH, gD, and gL function in the respective viral mutants (B. G. Klupp and T. C. Mettenleiter, J. Virol. 73:3014-3022, 1999). Cotransfection of plasmids encoding PrV gC, gE, gI, gK, and UL20 with gB-008 and gDH had no effect on fusion. However, inclusion of a gM-expressing plasmid strongly reduced the extent of fusion. An inhibitory effect was also observed after inclusion of plasmids encoding gM homologs of equine herpesvirus 1 or infectious laryngotracheitis virus but only in conjunction with expression of the gM complex partner, the gN homolog. Inhibition by PrV gM was not limited to PrV glycoprotein-mediated fusion but also affected fusion induced by the F protein of bovine respiratory syncytial virus, indicating a general mechanism of fusion inhibition by gM.

The EICP22 protein of equine herpesvirus 1 physically interacts with the immediate-early protein and with itself to form dimers and higher-order complexes

The EICP22 protein (EICP22P) of Equine herpesvirus 1 (EHV-1) is an early protein that functions synergistically with other EHV-1 regulatory proteins to transactivate the expression of early and late viral genes. We have previously identified EICP22P as an accessory regulatory protein that has the ability to enhance the transactivating properties and the sequence-specific DNA-binding activity of the EHV-1 immediate-early protein (IEP). In the present study, we identify EICP22P as a self-associating protein able to form dimers and higher-order complexes during infection. Studies with the yeast two-hybrid system also indicate that physical interactions occur between EICP22P and IEP and that EICP22P self-aggregates. Results from in vitro and in vivo coimmunoprecipitation experiments and glutathione S-transferase (GST) pull-down studies confirmed a direct protein-protein interaction between EICP22P and IEP as well as self-interactions of EICP22P. Analyses of infected cells by laser-scanning confocal microscopy with antibodies specific for IEP and EICP22P revealed that these viral regulatory proteins colocalize in the nucleus at early times postinfection and form aggregates of dense nuclear structures within the nucleoplasm. Mutational analyses with a battery of EICP22P deletion mutants in both yeast two-hybrid and GST pull-down experiments implicated amino acids between positions 124 and 143 as the critical domain mediating the EICP22P self-interactions. Additional in vitro protein-binding assays with a library of GST-EICP22P deletion mutants identified amino acids mapping within region 2 (amino acids [aa] 65 to 196) and region 3 (aa 197 to 268) of EICP22P as residues that mediate its interaction with IEP.

Characterization of the trans-activation properties of equine herpesvirus 1 EICP0 protein

The EICP0 protein of equine herpesvirus 1 (EHV-1) is an early, viral regulatory protein that independently trans-activates EHV-1 immediate-early (IE), early, gamma1 late, and gamma2 late promoters. To assess whether this powerful trans-activator functions in conjunction with three other EHV-1 regulatory proteins to activate expression of the various classes of viral promoters, transient cotransfection assays were performed in which effector plasmids expressing the EICP22, EICP27, and IE proteins were used either singly or in combination with an EICP0 effector construct. These analyses revealed that (i) independently, the EICP0 and IE proteins are powerful trans-activators but do not function synergistically, (ii) the IE protein inhibits the ability of the EICP0 protein to trans-activate the IE, gamma1 late, and gamma2 late promoters, (iii) the EICP22 and EICP0 proteins do not function together to significantly trans-activate any EHV-1 promoter, and (iv) the EICP27 and EICP0 proteins function synergistically to trans-activate the early and gamma1 late promoters. A panel of EICP0 truncation and deletion mutant plasmids was generated and used in experiments to define the domains of the 419-amino-acid (aa) EICP0 protein that are important for the trans-activation of each class of EHV-1 promoters. These studies revealed that (i) carboxy-terminal truncation mutants of the EICP0 protein exhibited a progressive loss of trans-activating ability as increasing portions of the carboxy terminus were removed, (ii) the amino terminus of the EICP0 protein containing the RING finger (aa 8 to 46) and the acidic region (aa 71 to 84) was necessary but not sufficient for activation of all classes of EHV-1 promoters, (iii) the RING finger was absolutely essential for activation of EHV-1 promoters, since deletion of the entire RING finger motif (aa 8 to 46) or a portion of it (aa 19 to 30) completely abrogated the ability of these mutants to activate any promoter tested, (iv) the acidic region contributed to the ability of the EICP0 protein to activate the early and gamma1 late promoters, and deletion of the acidic region enhanced the ability of this mutant to activate the IE promoter, (v) the carboxy terminus (aa 325 to 419), which is rich in glutamine residues, was dispensable for the EICP0 trans-activation function, (vi) a motif resembling a nuclear localization signal (aa 289 to 293) was unnecessary for the EICP0 protein to trans-activate promoters of any temporal class, and (vii) the EICP0 protein was phosphorylated during infection, and deletion of the serine-rich region (aa 210 to 217), a potential site for phosphorylation, reduced by more than 70% the ability of the EICP0 protein to activate the gamma2 late class of promoters.

The equine herpesvirus 1 Us2 homolog encodes a nonessential membrane-associated virion component

Experiments were conducted to analyze the equine herpesvirus 1 (EHV-1) gene 68 product which is encoded by the EHV-1 Us2 homolog. An antiserum directed against the amino-terminal 206 amino acids of the EHV-1 Us2 protein specifically detected a protein with an Mr of 34,000 in cells infected with EHV-1 strain RacL11. EHV-1 strain Ab4 encodes a 44,000-Mr Us2 protein, whereas vaccine strain RacH, a high-passage derivative of RacL11, encodes a 31,000-Mr Us2 polypeptide. Irrespective of its size, the Us2 protein was incorporated into virions. The EHV-1 Us2 protein localized to membrane and nuclear fractions of RacL11-infected cells and to the envelope fraction of purified virions. To monitor intracellular trafficking of the protein, the green fluorescent protein (GFP) was fused to the carboxy terminus of the EHV-1 Us2 protein or to a truncated Us2 protein lacking a stretch of 16 hydrophobic amino acids at the extreme amino terminus. Both fusion proteins were detected at the plasma membrane and accumulated in the vicinity of nuclei of transfected cells. However, trafficking of either GFP fusion protein through the secretory pathway could not be demonstrated, and the EHV-1 Us2 protein lacked detectable N- and O-linked carbohydrates. Consistent with the presence of the Us2 protein in the viral envelope and plasma membrane of infected cells, a Us2-negative RacL11 mutant (L11DeltaUs2) exhibited delayed penetration kinetics and produced smaller plaques compared with either wild-type RacL11 or a Us2-repaired virus. After infection of BALB/c mice with L11DeltaUs2, reduced pathogenicity compared with the parental RacL11 virus and the repaired virus was observed. It is concluded that the EHV-1 Us2 protein modulates virus entry and cell-to-cell spread and appears to support sustained EHV-1 replication in vivo.

Construction and characterization of an equine herpesvirus 1 glycoprotein C negative mutant

An equine herpesvirus 1 (EHV-1) strain RacL 11 mutant was constructed that carries the Escherichia coli LacZ gene instead of the open reading frame encoding glycoprotein C (gC). The engineered virus mutant (L11(delta)gC) lacked codons 46-440 of the 1404 bp gene. On rabbit kidney cell line Rk13 and equine dermal cell line Edmin337, the L11(delta)gC virus grew to titers which were reduced by approximately 5- to 10-fold compared with wild-type RacL11 virus or a repaired virus (R-L11(delta)gC). However, when L11(delta)gC growth properties were analyzed on primary equine cells a decrease of viral titers was observed such that extracellular L11(delta)gC titers were reduced by 48- to 210-fold compared with those of wild-type or repaired virus. Heparin sensitive and heparin resistant attachment was assessed by binding studies using radiolabeled virion preparations. These studies revealed that EHV-1 gC is important for heparin sensitive attachment to the target cell. Similar results were obtained when cellular glycosaminoglycan (GAG) synthesis was inhibited by chlorate treatment or when cells defective in GAG synthesis were used. L11(delta)gC also exhibited significantly delayed penetration kinetics on Rk13 and primary equine cells. Infection of mice with L11(delta)gC did not cause EHV-1-related disease, whereas mice infected with either RacL11 or R-L11(delta)gC exhibited massive bodyweight losses, high virus titers in the lungs, and viremia. Taken together, EHV-1 gC was shown to play important roles in the early steps of infection and in release of virions, especially in primary equine cells, and contributes to EHV-1 virulence.

The equine herpesvirus 1 IR6 protein that colocalizes with nuclear lamins is involved in nucleocapsid egress and migrates from cell to cell independently of virus infection

The equine herpesvirus 1 (EHV-1) IR6 protein forms typical rod-like structures in infected cells, influences virus growth at elevated temperatures, and determines the virulence of EHV-1 Rac strains (Osterrieder et al., Virology 226:243-251, 1996). Experiments to further elucidate the functions and properties of the IR6 protein were conducted. It was shown that the IR6 protein of wild-type RacL11 virus colocalizes with nuclear lamins very late in infection as demonstrated by confocal laser scan microscopy and coimmunoprecipitation experiments. In contrast, the mutated IR6 protein encoded by the RacM24 strain did not colocalize with the lamin proteins at any time postinfection (p.i.). Electron microscopical examinations of ultrathin sections were performed on cells infected at 37 and 40 degreesC, the latter being a temperature at which the IR6-negative RacH virus and the RacM24 virus are greatly impaired in virus replication. These analyses revealed that nucleocapsid formation is efficient at 40 degreesC irrespective of the virus strain. However, whereas cytoplasmic virus particles were readily observed at 16 h p.i. in cells infected with the wild-type EHV-1 RacL11 or an IR6-recombinant RacH virus (HIR6-1) at 40 degreesC, virtually no capsid translocation to the cytoplasm was obvious in RacH- or RacM24-infected cells at the elevated temperature, demonstrating that the IR6 protein is involved in nucleocapsid egress. Transient transfection assays using RacL11 or RacM24 IR6 plasmid DNA and COS7 or Rk13 cells, infection studies using a gB-negative RacL11 mutant (L11DeltagB) which is deficient in direct cell-to-cell spread, and studies using lysates of IR6-transfected cells demonstrated that the wild-type IR6 protein is transported from cell to cell in the absence of virus infection and can enter cells by a yet unknown mechanism.

Phosphorylation of structural components promotes dissociation of the herpes simplex virus type 1 tegument

The role of phosphorylation in the dissociation of structural components of the herpes simplex virus type 1 (HSV-1) tegument was investigated, using an in vitro assay. Addition of physiological concentrations of ATP and magnesium to wild-type virions in the presence of detergent promoted the release of VP13/14 and VP22. VP1/2 and the UL13 protein kinase were not significantly solubilized. However, using a virus with an inactivated UL13 protein, we found that the release of VP22 was severely impaired. Addition of casein kinase II (CKII) to UL13 mutant virions promoted VP22 release. Heat inactivation of virions or addition of phosphatase inhibited the release of both proteins. Incorporation of radiolabeled ATP into the assay demonstrated the phosphorylation of VP1/2, VP13/14, VP16, and VP22. Incubation of detergent-purified, heat-inactivated capsid-tegument with recombinant kinases showed VP1/2 phosphorylation by CKII, VP13/14 phosphorylation by CKII, protein kinase A (PKA), and PKC, VP16 phosphorylation by PKA, and VP22 phosphorylation by CKII and PKC. Proteolytic mapping and phosphoamino acid analysis of phosphorylated VP22 correlated with previously published work. The phosphorylation of virion-associated VP13/14, VP16, and VP22 was demonstrated in cells infected in the presence of cycloheximide. Use of equine herpesvirus 1 in the in vitro release assay resulted in the enhanced release of VP10, the homolog of HSV-1 VP13/14. These results suggest that the dissociation of major tegument proteins from alphaherpesvirus virions in infected cells may be initiated by phosphorylation events mediated by both virion-associated and cellular kinases.

Synthesis and processing of the equine herpesvirus 1 glycoprotein M

In a previous report, the function of the equine herpesvirus 1 (EHV-1) glycoprotein M (gM) homolog was investigated. It was shown that EHV-1 gM is involved in both virus entry and direct cell-to-cell spread of infection (N. Osterrieder et al., J. Virol. 70, 4110-4115, 1996). In this study, experiments were conducted to analyze the synthesis, posttranslational processing, and the putative ion channel function of EHV-1 gM. It was demonstrated that EHV-1 gM is synthesized as an Mr 44,000 polypeptide, which is cotranslationally N-glycosylated to an Mr 46,000-48,000 glycoprotein. The Mr 46,000-48,000 gM moiety is processed to an Mr 50,000-55,000 glycoprotein, which is resistant to treatment with endoglycosidase H, indicating that processing occurs in the Golgi network. EHV-1 gM forms a dimer in infected cells and the virion, as was demonstrated by the presence of an Mr 105,000-110,000 gM-containing band in electrophoretically separated lysates of infected cells and purified extracellular virions. The Mr 105,000-110,000 protein band containing gM was also observed in lysates of cells that had been transfected with EHV-1 gM DNA. The translation of EHV-1 gM is initiated at the first in-frame methionine of the gM open reading frame as shown by transient transfection experiments of full-length gM and a truncated gM lacking the aminoterminal 83 amino acids. Functional expression of EHV-1 gM in Xenopus laevis oocytes together with voltage-clamp analyses demonstrated that gM per se does not exhibit ion channel activity as had been speculated from the predicted structure of the polypeptide.

Structural and antigenic identification of the ORF12 protein (alpha TIF) of equine herpesvirus 1

The equine herpesvirus 1 (EHV-1) homolog of the herpes simplex virus type 1 (HSV-1) tegument phosphoprotein, alpha TIF (Vmw65; VP16), was identified previously as the product of open reading frame 12 (ORF12) and shown to transactivate immediate early (IE) gene promoters. However, a specific virion protein corresponding to the ORF12 product has not been identified definitively. In the present study the ORF12 protein, designated ETIF, was identified as a 60-kDa virion component on the basis of protein fingerprint analyses in which the limited proteolysis profiles of the major 60-kDa in vitro transcription/ translation product of an ORF12 expression vector (pT7-12) were compared to those of purified virion proteins of similar size. ETIF was localized to the viral tegument in Western blot assays of EHV-1 virions and subvirion fractions using polyclonal antiserum and monoclonal antibodies generated against a glutathione-S-transferase-ETIF fusion protein. Northern and Western blot analyses of EHV-1-infected cell lysates prepared under various metabolic blocks indicated that ORF12 is expressed as a late gene, and cross reaction of polyclonal anti-GST-ETIF with a 63.5-kDa HSV-1 protein species suggested that ETIF and HSV-1 alpha TIF are antigenically related. Last, DNA band shift assays used to assess ETIF-specific complex formation indicated that ETIF participates in an infected cell protein complex with the EHV-1 IE promoter TAATGARAT motif.

Expression and function of the equine herpesvirus 1 virion-associated host shutoff homolog

The ability of herpes simplex virus types 1 and 2 (HSV-1 and HSV-2, respectively) to repress host cell protein synthesis early in infection has been studied extensively and found to involve the activities of the UL41 gene product, the virion-associated host shutoff (vhs) protein. To date, UL41 homologs have been identified in the genomes of three other alphaherpesviruses: equine herpesvirus 1 (EHV-1), varicella-zoster virus, and pseudorabies virus, but very little is known about the putative products of these homologous genes. Our earlier observations that no rapid early host protein shutoff occurred in EHV-1-infected cells led us to test EHV-1 vhs activity more thoroughly and to examine the expression and function of the EHV-1 UL41 homolog, ORF19. In the present study, the effects of EHV-1 and HSV-1 infections on cellular protein synthesis and mRNA degradation were compared at various multiplicities of infection in several cell types under an actinomycin D block. No virion-associated inhibition of cellular protein synthesis or vhs-induced cellular mRNA degradation was detected in cells infected with any of three EHV-1 strains (Ab4, KyA, and KyD) at multiplicities of infection at which HSV-1 strain F exhibited maximal vhs activity. However, further analyses revealed that (i) the EHV-1 vhs homolog gene, ORF19, was transcribed and translated into a 58-kDa protein in infected cells; (ii) the ORF19 protein was packaged into viral particles in amounts detectable in Western blots (immunoblots) with monoclonal antibodies; (iii) in cotransfection vhs activity assays, transiently-expressed ORF19 protein had intrinsic vhs activity comparable to that of wild-type HSV-1 vhs; and (iv) this intrinsic vhs activity was ablated by in vitro site-directed mutations in which either the functionally inactive HSV-1 vhs1 UL41 mutation (Thr at position 214 replaced by Ile [Thr-214-->Ile]) was recreated within ORF19 or two conserved residues within the putative poly(A) binding region of the ORF19 sequence were altered (Tyr-190, 192-->Phe). From these results we conclude that EHV-1's low vhs activity in infected cells is not a reflection of the ORF19 protein's intrinsic vhs activity but may be due instead to the amount of ORF19 protein associated with viral particles or to modulation of ORF19 protein's intrinsic activity by another viral component(s).

N-terminal sequence analysis of equine herpesvirus 1 glycoproteins D and B and evidence for internal cleavage of the gene 71 product

Signal cleavage sites of equine herpesvirus 1 (EHV-1) glycoproteins D and B (gD and gB) and an endoproteolytic cleavage site of EHV-1 gB were determined by N-terminal amino acid sequencing and compared with known cleavage sites of homologues in other herpesvirus. Signal cleavage of EHV-1 gD occurred between Arg35 and Ala36 in a region of basic amino acids resembling the endoproteolytic cleavage sites of viral glycoproteins, nine amino acids downstream of the predicted site, while EHV-1 gB was cleaved as predicted between Ala85 and Val86. Endoproteolytic cleavage of EHV-1 gB occurred between Arg548 and Ala549, 28 amino acids downstream of the cleavage site predicted from conserved sequences of other herpesvirus gB homologous. One interpretation of these data is that EHV-1 gB is cleaved internally at both sites, a possibility which was supported by the apparent molecular masses of the unglycosylated gB subunits produced in the presence of tunicamycin. This double cleavage would release a stretch of amino acids which is not present in sequenced gB molecules of other herpesviruses. Experiments with glycosylation inhibitors indicated that cleavage of EHV-1 gB can occur in the absence of glycosylation. N-terminal sequencing also determined that a 42 kDa EHV-1 glycoprotein was a product of internal cleavage of the protein encoded by gene 71. Staggered endoproteolytic cleavage after adjacent arginine residues 506 and 507 separates the 42 kDa C-terminal subunit containing all the cysteine residues from the serine and threonine rich N-terminal region.

Expression of an equine herpesvirus 1 ICP22/ICP27 hybrid protein encoded by defective interfering particles associated with persistent infection

Defective interfering (DI) particles of equine herpesvirus type 1 (EHV-1) are capable of mediating persistent infection (S. A. Dauenhauer, R. A. Robinson, and D. J. O'Callaghan, J. Gen. Virol. 60:1-14, 1982; R. A. Robinson, R. B. Vance, and D. J. O'Callaghan, J. Virol. 36:204-219, 1980). Sequence analysis of cloned DI particle DNA revealed that portions of two regulatory genes, ICP22 (IR4) and ICP27 (UL3), are linked in frame to form a unique hybrid open reading frame (ORF). This hybrid ORF, designated as the IR4/UL3 gene, encodes the amino-terminal 196 amino acids of the IR4 protein (ICP22 homolog) and the carboxy-terminal 68 amino acids of the UL3 protein (ICP27 homolog). Portions of DNA sequences encoding these two regulatory proteins, separated by more than 115 kbp in the standard virus genome, were linked presumably by a homologous recombination event between two identical 8-bp sequences. Reverse transcriptase-PCR and S1 nuclease analyses revealed that this unique ORF is transcribed by utilizing the transcription initiation site of ICP22 and the polyadenylation signal of ICP27 in DI particle-enriched infection. Immunoprecipitation and Western blot (immunoblot) analyses with antisera to the ICP22 and ICP27 proteins demonstrated that a 31-kDa hybrid protein was synthesized in the DI particle-enriched infection but not in standard virus infection. This 31-kDa hybrid protein was expressed at the same time as the ICP22 protein in DI particle-enriched infection and migrated at the same location on polyacrylamide gel electrophoresis as the protein expressed from a cloned IR4/UL3 expression vector. These observations suggested that the unique IR4/UL3 hybrid gene is expressed from the DI particle genome and may play a role in DI particle-mediated persistent infection.

Pseudorabies virus and equine herpesvirus 1 share a nonessential gene which is absent in other herpesviruses and located adjacent to a highly conserved gene cluster

We have determined the nucleotide sequence and transcriptional pattern of a group of open reading frames in the pseudorabies virus (PrV) genome located near the left end of the unique long region within BamHI 5' fragment at map positions 0.01 to 0.06. The 7,412-bp BamHI 5' fragment was found to contain five complete open reading frames and part of a sixth whose deduced amino acid sequences showed homology to the UL50 (partial), UL51, UL52, UL53, and UL54 gene products of herpes simplex virus type 1 (HSV-1) and corresponding genes identified in other alphaherpesviruses. Homologs to the UL55 and UL56 genes of HSV-1 were not detected. However, we identified a gene with homology only to the first open reading frame (ORF-1) of the equine herpesvirus 1 strain Ab4 (E. A. Telford, M. S. Watson, K. McBride, and A. J. Davison, Virology 189:304-316, 1992). Northern blot analyses revealed unique mRNAs for the UL51, UL54, and ORF-1 genes and a set of 3'-coterminal mRNAs for the UL52 to UL54 genes. A PrV mutant lacking ORF-1 was isolated after deletion of ORF-1 coding sequences and insertion of a lacZ expression cassette. The ORF-1- PrV mutant was able to productively replicate in noncomplementing cells to levels similar to those of wild-type PrV, proving that ORF-1 is not essential for replication of PrV in cell culture. The conservation of this gene between PrV and equine herpesvirus 1 documents the close evolutionary relationship between these animal herpesviruses and points to a possible function of the respective proteins in infection of the natural host.

Characteristics of equine herpesvirus 1 glycoproteins expressed in insect cells

A series of recombinant baculoviruses containing genes for glycoproteins C, D, H and L of equine herpesvirus 1 (EHV-1) have been constructed, and the EHV-1 products characterised by gel electrophoresis and immunoblotting. The EHV-1 glycoproteins expressed in insect cells were similar but not identical in apparent sizes to those expressed in EHV-1 infected mammalian cells. Each of the EHV-1 products was recognised by convalescent equine sera, indicating that they were all targets for an equine immune response. Mice immunised with baculovirus-expressed EHV-1 gD and gC acquired an enhanced ability to clear challenge EHV-1 from respiratory tissues, in association with both neutralising antibody and cell mediated immune responses.

Detection and intracellular localization of equine herpesvirus 1 IR1 and IR2 gene products by using monoclonal antibodies

During lytic infection, two transcripts arise from the equine herpesvirus 1 (EHV-1) immediate-early (IE) gene (IR1): a single, spliced 6.0-kb IE mRNA and a 3'-coterminal 4.4-kb early mRNA (IR2). Previous studies demonstrated that transiently expressed IR1 and IR2 gene products are potent transcriptional regulators: IR1 proteins are capable of trans activating representative EHV-1 early and late promoters, while both IR1 proteins and the IR2 product, which lacks IR1 amino acid residues 1 to 322, trans repress the IR1 promoter. In the present study, monoclonal antibodies (MAbs) against the major IE protein, IE1, were developed, characterized as to their ability to detect IR1 and IR2 products, and used to examine extracellular virions for the presence of IE1-related proteins and to define the IR1 and IR2 protein synthesis and intracellular distribution in EHV-1-infected cells. The results demonstrated that (i) anti-IE1 MAbs representing three noncompetitive epitope-binding groups reacted with multiple IE protein species, as well as with a 146-kDa early protein identified as the putative IR2 gene product; (ii) the three reactive epitopes mapped to a region spanning amino acids 323 to 552 of IR1; (iii) anti-IE1 MAbs reacted with the 144-kDa in vitro-translated IR2 product and with a transiently expressed IR2 product similar in size; (iv) small amounts of IE1 and the 146-kDa protein were associated with the nucleocapsid-tegument fraction of mature virions; (v) in immunofluorescence assays of lytically infected cells, IR1-IR2 gene products were first detectable between 1 and 2 h postinfection as discrete, punctate, intranuclear foci; (vi) as the infection progressed, the intranuclear reactivity increased and redistributed into large, intensely stained nuclear compartments which corresponded to the sites of active viral DNA synthesis; (vii) fibrillar, as well as more generalized cytoplasmic staining, first observed at about 5 h postinfection, increased throughout infection; and (viii) while viral DNA synthesis was required for the progressive intranuclear redistribution, the cytoplasmic accumulation of IR1-IR2 proteins occurred subsequent to early infection events.

Synthesis and processing of equine herpesvirus 1 glycoprotein D

Previous studies (C. C. Flowers and D. J. O'Callaghan, 1992, Virology 190, 307-315) employed peptide-specific antibodies to identify the product of the glycoprotein D (gD) gene of equine herpesvirus 1 strain Kentucky A (KyA). gD polypeptides of 55 and 58 kDa were detected in EHV-1-infected L-M cells, and the 58-kDa protein was observed in the membrane fraction of EHV-1 virions. In this report, the kinetics of synthesis and processing of gD polypeptides are described. One-hour pulse-labeling of EHV-1-infected L-M cells revealed that gD proteins are first detected at 6 hr after infection and that maximal synthesis of gD occurs between 5 and 8 hr postinfection. gD polypeptides accumulate progressively with time of infection as shown by immunoprecipitation analysis of gD proteins. Pulse-chase analysis of gD revealed that the 55-kDa protein is a precursor to the 58-kDa species and that processing of all pulse-labeled precursor protein requires approximately 2.5 hr. Analysis of the carbohydrate content of gD proteins, as judged by their sensitivity to digestion with endoglycosidases, revealed that the 55-kDa gD precursor contains high-mannose N-linked oligosaccharides, while the 58-kDa gD mature polypeptide possesses complex type oligosaccharides. Expression of the mature form of gD on the cell surface, as determined by fluorescent flow cytometric analysis, is delayed compared to the accumulation of the mature form of gD within the cell. The gD ORF encodes a potential protein of 442 amino acids but analysis of the translated sequence of gD indicated that the gD polypeptide is 392 amino acids, a size predicted by previous mapping of the transcription start site of the gD mRNA. Coupled in vitro transcription/translation of a pGEM-3Z construct containing the 392-amino-acid gD ORF, in the absence or presence of canine pancreatic microsomes, demonstrated that the 43-kDa gD polypeptide undergoes processing in vitro. These studies demonstrate that the EHV-1 strain KyA gD is processed in a fashion similar to that of the gD proteins of other alphaherpesviruses.

Characterization and localization of the equine herpesvirus 1 major DNA binding protein

In previous studies of equine herpesvirus 1 (EHV-1) gene regulation, we observed an abundant early infected cell polypeptide (ICP), designated ICP130, which appeared in reduced amounts in cells infected with defective interfering particle-rich EHV-1 stocks compared to standard EHV-1-infected cells. To characterize this ICP further, a monoclonal antibody (MAb) was developed to EHV-1 ICP130 and used to (1) affinity purify ICP130, (2) examine ICP130's ability to bind DNA, and (3) define the synthesis and intracellular localization of ICP130 during productive EHV-1 infections. Although anti-ICP130 MAbs did not crossreact with any HSV-1 protein in immunoblots, a polyclonal antiserum against HSV-2 major DNA binding protein (ICSP11,12) did react with purified EHV-1 ICP130. DNA band shift assays indicated that (1) the mobility of shifted bands representing DNA/EHV-1-infected cell protein complexes was further decreased by the addition of either anti-ICP130 MAbs or anti-ICSP11,12, but not by the addition of irrelevant MAbs, (2) the ability of ICP130 to complex with DNA was not sequence dependent, (3) ICP130 associated with both single- and double-stranded oligomers, and (4) similar supershifted patterns were produced using affinity-purified ICP130 and anti-ICP130 MAbs. During productive infection, ICP130 initially localized rapidly and exclusively to the infected cell's nucleus in a generalized, fine granular pattern. Over the course of infection, this pattern typically progressed to include several large, intensely reactive intranuclear granules, and by 6 hr p.i. some cytoplasmic reactivity also was visible. In < 5% of the cells, a dense, fibrillar network surrounding the nucleus was observed instead. The progressive changes in nuclear localization depended upon the onset of viral DNA replication, and once the late pattern was established, ongoing DNA synthesis was required to maintain it. The results indicate that ICP130 is the previously reported EHV-1 counterpart of the HSV major DNA-binding protein and is similar, but not identical, in many aspects.

Identification and characterization of the protein product of gene 71 in equine herpesvirus 1

Equine herpesvirus 1 (EHV-1) strain Ab4 gene 71 is predicted to encode a primary product with a M(r) of 80.1K. We have previously constructed a deletion/lacZ insertion mutant, ED71, and demonstrated that gene 71 is dispensable for growth of virus in cell culture. We have now constructed a gene 71 revertant, Re71. To identify and characterize the product of gene 71, we produced a specific antiserum, anti-71, against a beta-galactosidase fusion protein containing the carboxy terminus of the gene 71 polypeptide. Using the anti-71 serum, mutant ED71 and the revertant Re71, we have demonstrated that gene 71 encodes a 192K polypeptide. Experiments with glycosylation inhibitors revealed that the protein product of gene 71 is N-glycosylated and heavily O-glycosylated. When the 192K polypeptide is synthesized in the presence of monensin, the M(r) of the polypeptide is reduced to 80K, the predicted unmodified M(r) of the gene 71 polypeptide. The gene 71 product is found in virions and L particles in a fully processed form that runs as a diffuse band in electrophoresis, with a M(r) in excess of 200K. Immunofluorescence and virion surface labelling experiments showed that the polypeptide product of gene 71 is located on cellular membranes and the virion envelope. A time course of infection confirmed that gene 71 is regulated as a leaky late gene in infected cells. Finally, using wild-type EHV-1 Ab4, mutant ED71, revertant Re71 and two antibodies (P19 against EHV-1 glycoprotein gp300, and anti-71) we conclusively demonstrated that gene 71 encodes gp300. This contradicts published results with P19 alone, which indicated gp300 was the product of EHV-1 gene 28.

Identification and characterization of the ICP22 protein of equine herpesvirus 1

The equine herpesvirus 1 (EHV-1) homolog of herpes simplex virus type 1 ICP22 is differently expressed from the fourth open reading frame of the inverted repeat (IR4) as a 1.4-kb early mRNA and a 1.7-kb late mRNA which are 3' coterminal (V. R. Holden, R. R. Yalamanchili, R. N. Harty, and D. J. O'Callaghan, J. Virol. 66:664-673, 1992). To extend the characterization of IR4 at the protein level, the synthesis and intracellular localization of the IR4 protein were investigated. Antiserum raised against either a synthetic peptide corresponding to amino acids 270 to 286 or against a TrpE-IR4 fusion protein (IR4 residues 13 to 150) was used to identify the IR4 protein. Western immunoblot analysis revealed that IR4 is expressed abundantly from an open reading frame composed of 293 codons as a family of proteins that migrate between 42 to 47 kDa. The intracellular localization of IR4 was examined by cell fractionation, indirect immunofluorescence, and laser-scanning confocal microscopy. These studies revealed that IR4 is localized predominantly in the nucleus and is dispersed uniformly throughout the nucleus. Interestingly, when IR4 is expressed transiently in COS-1 or LTK- cells, a punctate staining pattern within the nucleus is observed by indirect immunofluorescence. Cells transfected with an IR4 mutant construct that encodes a C-terminal truncated (19 amino acids) IR4 protein exhibited greatly reduced intranuclear accumulation of the IR4 protein, indicating that this domain possesses an important intranuclear localization signal. Western blot analysis of EHV-1 virion proteins revealed that IR4 proteins are structural components of the virions. Surprisingly, the 42-kDa species, which is the least abundant and the least modified form of the IR4 protein family in infected cell extracts, was the most abundant IR4 protein present in purified virions.

Cloning and expression of an equine herpesvirus 1 origin-binding protein

Equine herpesvirus 1 (EHV-1) is an important pathogen of horses and is closely related to several important human pathogens, herpes simplex virus types 1 and 2 (HSV-1 and HSV-2) and varicella-zoster virus. The EHV-1 genome contains open reading frames similar in sequence to the HSV-1 replication genes. PCR was used to clone EHV-1 gene 53, which is similar in sequence to the HSV-1 UL9 gene. The gene 53 product has regions of striking similarity to the HSV-1 UL9 and VZV gene 51 products. In vitro transcription and translation of this gene generated a protein of 87 kDa as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Further characterization of this protein was accomplished through the use of gel shift analysis. The in vitro-synthesized protein bound sequence specifically to EHV-1 OriS as well as HSV-1 OriS. A site was used in gel shift analysis to show that the EHV-1 origin-binding protein bound to the same consensus site as the HSV-1 origin-binding protein, 5'-CGTTCGCACTT-3'. Using a nuclear extract of EHV-1-infected RK13 cells, we have identified an activity that interacts similarly with this consensus site. In gel shift assays, the retarded band arising from the nuclear extract migrated similarly to the retarded band arising from in vitro-translated EHV-1 gene 53. An N-terminal deletion of EHV-1 gene 53 was also created, expressed in vitro, and used in gel shift assays to localize the DNA-binding domain. Results of these experiments indicated that amino acids 1 to 499 were dispensable for binding and that the C-terminal fragment (amino acids 500 to 888) recognized the same consensus site as did the wild-type protein. Thus, the product of EHV-1 gene 53 is an origin-binding protein with a high degree of similarity to the HSV-1 and varicella-zoster virus origin-binding proteins and possibly serves as the initiator of DNA replication in EHV-1.

Comparative studies of the proteins of equine herpesviruses 4 and 1 and asinine herpesvirus 3: antibody response of the natural hosts

Proteins of purified virions of equine herpesvirus 4 (EHV-4; equine rhinopneumonitis), EHV-1 (equine abortion virus) and asinine herpesvirus 3 (AHV-3) were compared by metabolic labelling with [35S]methionine or [14C]glucosamine during growth of low passage virus in natural host cells (horse or donkey) and high passage virus in an appropriate cell line and analysis by SDS-PAGE. Approximately 25 different proteins (Mr 300K to 21.5K) were clearly resolved for each virus. The three viruses had similar profiles although significant differences were found. The proteins of the cell line-grown viruses were similar to their precursor viruses grown in natural host cells although some small differences, probably related to differences in glycosylation by the various cell types, were noted. Six or seven high abundance glycoproteins were identified for EHV-4, EHV-1 and AHV-3. The profile of seven glycoproteins of AHV-3 was more similar to EHV-1 than to EHV-4. Antigenic relationships of the proteins of the three viruses were examined using radioimmunoprecipitation (RIP) and Western blot analyses and a series of polyclonal sera raised in colostrum-deprived, specific pathogen-free (SPF) foals which were immunized with inactivated EHV-4 (foal 3) or EHV-1 (foal 1), challenged and cross-challenged; a polyclonal donkey serum to AHV-3 was also used. The ontogeny of the antibody response in the SPF foals was studied and the major immunogenic proteins, as determined by RIP, were correlated with previously determined serum neutralizing antibody titres. Antibodies were first detected 14 days after primary immunization and were directed to EHV-4 proteins of Mr 113K, 75K and 56K or EHV-1 proteins of 110K, 78K, 60K and 58K. Antibodies to these same three (EHV-4) or four (EHV-1) proteins, together with antibodies to the major capsid protein and proteins of 67K (EHV-4) and 87K (EHV-1) were detected in response to primary infection (control foal 2) and these sera had high neutralizating antibody titres. The antigens of the three viruses were extensively cross-reactive with immunodominant proteins in the Mr ranges 150K to 110K and 62K to 56K. However, cross-absorption of EHV-4 and EHV-1 SPF foal antisera indicated the presence of significant amounts of type-specific antibody.

Synthesis and processing of equine herpesvirus type 1 glycoprotein 14

Glycoprotein 14 (gp14) of equine herpesvirus type 1 (EHV-1), the homolog of herpes simplex virus (HSV) glycoprotein B (gB), was investigated employing a panel of monoclonal antibodies to ascertain the regulatory class, rate of synthesis, and type of glycosylation of this polypeptide. Application of immunoprecipitation, Western blot, and SDS-PAGE analysis in conjunction with the use of metabolic inhibitors (cycloheximide, antinomycin D, phosphonoacetic acid, tunicamycin, and monensin), and time-course and pulse-chase experiments revealed the following information: (1) Three gp14-related polypeptides with molecular weights of 138 kilodaltons (K), 77-75K, and 55-53K are present in EHV-1-infected cell extracts. (2) All three species are synthesized in the presence of the DNA synthesis inhibitor phosphonoacetic acid although their synthesis is enhanced by DNA replication, indicative of a beta-gamma class molecule. (3) The 138K species is synthesized first as a precursor of the smaller species of gp14, the 77-75K and 55-53K forms. (4) Use of glycosylation inhibitors and digestion of immunoprecipitated gp14 with endoglycosidases indicate that the primary translation product is a 118K molecule which is cotranslationally glycosylated to the 138K form by the addition of high mannose oligosaccharides. (5) The 77-75K species contains both high mannose and hybrid oligosaccharides while the 55-53K form of gp14 contains some complex oligosaccharides. (6) In the absence of a reducing agent, the 138K polypeptide and a large 145K species are observed in both infected cell extracts and purified virions. Thus, EHV-1 gp14 appears to be synthesized as a large precursor molecule of 138K and is proteolytically cleaved to two smaller forms, 77-75K and 55-53K, which are linked by a disulfide bond(s) to form a 145K complex. This model of gp14 synthesis and maturation is similar to those proposed for a number of HSV gB equivalents found in the Alphaherpesvirnae.

Molecular pathogenesis of equine coital exanthema: temperature-sensitive function(s) in cells infected with equine herpesviruses

Preliminary experiments have revealed that several laboratory and wild-type strains of the equine herpesvirus (EHV) triad were temperature-sensitive for growth when assayed at 39 degrees C. The efficiencies of plating (EOP) observed were 10(-2) for both EHV 1 and 2, and 1 X 10(-6) for EHV 3. The EOPs were determined by plaque assays which compared titrations at 34 degrees C and 39 degrees C on equine fetal dermal fibroblast cells. Growth yield experiments, assayed at 34 degrees C, reflected those EOP's, but did not indicate any difference in yields when infected cultures were incubated at 34 degrees C and 37 degrees C. Temperature shift experiments with EHV 3-infected cultures revealed that a temperature-sensitive function(s) responsible for the reduction in titer appeared to be a late function(s). All strains examined appeared to incorporate H3-thymidine into viral-density DNA at the non-permissive temperature of 39 degrees C. Electron microscopy of EHV 3-infected cell cultures, incubated continuously at the non-permissive temperature and examined at 18 h after infection, revealed structures consistent with the accumulation of nucleocapsids within the nucleus. The evidence presented is consistent with the hypothesis that in equine dermal cells infected with a plaque-purified wild-type strain of EHV 3 (1118LP), a function needed for the egress of nucleocapsids from the nucleus is absent at 39 degrees C. The significance of these findings relative to the pathogenicity of the disease (equine coital exanthema) caused by this virus is discussed.

Equine herpesvirus type 1 infected cell polypeptides: evidence for immediate early/early/late regulation of viral gene expression

EHV-1 polypeptide synthesis was examined in productively infected rabbit kidney and hamster embryo cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analyses of extracts from [35S]methionine- and 3H-amino acid-labeled-infected and mock-infected cultures revealed the presence of 30 infected cell-specific polypeptides (ICPs) which ranged in apparent molecular weights from 16.5K to 213K. Twenty-two of these ICPs comigrated with virion structural proteins. Four ICPs (203K, 176K, 151K, 129K) were detected in extracts of infected cultures labeled in the presence or absence of actinomycin D (Act D) immediately after release from a 4-hr treatment with cycloheximide (CH). These polypeptides, which were designated as EHV-1 immediate early (alpha) ICPs, were not detected in unblocked (non-CH-treated) infected cells. The most abundant ICP was a 31.5K nonstructural protein which, in addition to a 74K protein, was detected in unblocked infected cells at 2-3 hr postinfection. These proteins appeared to be regulated as early (beta) ICPs, since neither protein was observed in Act D-treated cultures released from CH block. Twelve ICPs were classified as late (gamma) polypeptides on the basis of their reduced synthesis in cultures in which viral DNA replication was inhibited by phosphonoacetic acid. All but one (40K) of these late ICPs corresponded to virion structural proteins.