Influence of infectious dose upon productive replication and transynaptic passage of pseudorabies virus in rat central nervous system.

Pseudorabies virus (PRV) is a neurotropic swine alpha herpesvirus that characteristically invades the nervous system and replicates within synaptically-linked populations of neurons. The invasive characteristics and ability of this family of viruses to replicate in neurons of the central nervous system (CNS) have been exploited to map functionally related populations of neurons in a variety of systems. In this report, we examined the effects of strain and concentration on the ability of PRV to infect retinal ganglion cells and pass transneuronally through central visual circuits. We find that the ability of virulent (PRV-Becker) and attenuated (PRV-Bartha) strains of PRV to produce a productive infection of visual circuitry is directly dependent upon the infectious of the injected virus. Injections of at least 10(5) total plaque forming units produce 100% infectivity, whereas lower infectious doses substantially reduce the percentage of animals exhibiting productive infection via this route of inoculation. Furthermore, the virulent strain of PRV consistently infects a higher percentage of animals across a broader range of titers than attenuated virus. These data demonstrate that viral titer and strain are important variables that should be considered in the design of studies and interpretation of data derived from investigations employing this pathogen for circuit analysis.

Complementation analysis of pseudorabies virus gE and gI mutants in retinal ganglion cell neurotropism.

Pseudorabies virus glycoproteins gE and gI are required to infect some, but not all, regions of the rodent central nervous system after peripheral injection. After infection of the retina, pseudorabies virus mutants lacking either gE or gI can subsequently infect neural centers involved in the control of circadian function but cannot infect visual circuits mediating visual perception or the reflex movement of the eyes. In this study, we used genetic complementation to test the hypothesis that gE and gI are required for entry into the specific retinal ganglion cells that project to visual centers. These data strongly suggest that gE and gI must function after the viruses enter primary neurons in the retina.

Specific pseudorabies virus infection of the rat visual system requires both gI and gp63 glycoproteins.

Transneuronal transport of pseudorabies virus (PRV) from the retina to visual centers that mediate visual discrimination and reflexes requires specific genes in the unique short region of the PRV genome. In contrast, these same viral genes are not required to infect retinorecipient areas of the brain involved in circadian rhythm regulation. In this report, we demonstrate that viral mutants carrying defined deletions of the genes encoding glycoprotein gI or gp63, or both, result in the same dramatic transport defect. Efficient export of either gI or gp63 from the endoplasmic reticulum to the Golgi apparatus in a fibroblast cell line requires the presence of both proteins. We also show that gI and gp63 physically interact, as demonstrated by pulse-chase and sucrose gradient sedimentation experiments. Complex formation is rapid compared with homodimerization of PRV glycoprotein gII. We suggest that gI and gp63 function in concert to affect neurotropism in the rat visual circuitry and that a heterodimer is likely to be the unit of function.

A cellular function is required for pseudorabies virus envelope glycoprotein processing and virus egress.

The mouse L-cell mutant gro29 is defective for egress of herpes simplex virus type 1 (HSV-1) virions and is significantly reduced in HSV-1 glycoprotein export (B. W. Banfield and F. Tufaro, J. Virol. 64:5716-5729, 1990). In this report, we demonstrate that pseudorabies virus (PRV), a distantly related alphaherpesvirus, shows a distinctive set of defects after infection of gro29 cells. Specifically, we identify defects in the rate and extent of viral glycoprotein export, infectious particle formation, plaque formation, and virus egress. The initial rate of viral glycoprotein synthesis was unaffected in gro29 cells, but the extent of export from the endoplasmic reticulum to the Golgi apparatus was impaired and export through the Golgi apparatus became essentially blocked late in infection. Moreover, by using a secreted variant of a viral membrane protein, we found that export from the Golgi apparatus out of the cell was also defective in gro29 cells. PRV does not form plaques on gro29 monolayers. A low level of infectious virus is formed and released early after infection, but further virus egress is blocked. Taken together, these observations suggest that the gro29 phenotype involves either multiple proteins or a single protein used at multiple steps in viral glycoprotein export and virus egress from cells. Moreover, this host cell protein is required by both HSV and PRV for efficient propagation in infected cells.

Pseudorabies virus envelope glycoprotein gI influences both neurotropism and virulence during infection of the rat visual system.

We previously demonstrated that intraocular injections of virulent and attenuated strains of pseudorabies virus (PRV) produce transneuronal infection of functionally distinct central visual circuits in the rat. The virulent Becker strain of PRV induces two temporally separated waves of infection that ultimately target all known retinorecipient neurons; the attenuated Bartha strain only infects a functionally distinct subset of these neurons. In this study, we demonstrate that deletion of a single viral gene encoding glycoprotein gI is sufficient to reproduce both the novel pattern of infectivity and the reduced neurovirulence of the Bartha strain of PRV. Glycoprotein gIII, a major viral membrane protein required for efficient adsorption of virus in cell culture, has no obvious role in determining the pattern of neuronal infectivity, but appears to function with gI to influence neurovirulence. These data suggest that neuroinvasiveness and virulence are the products of an interaction of viral envelope glycoproteins with as yet unidentified cellular receptors.

The gIII glycoprotein of pseudorabies virus is involved in two distinct steps of virus attachment.

The entry of herpesviruses into cells involves two distinct stages: attachment or adsorption to the cell surface followed by internalization. The virus envelope glycoproteins have been implicated in both stages. Pseudorabies virus attaches to cells by an early interaction that involves the viral glycoprotein gIII and a cellular heparinlike substance. We examined the role of gIII in the attachment process by analysis of a set of viruses carrying defined gIII mutations. The initial attachment of gIII mutants with an internal deletion of 134 amino acids (PrV2) to MDBK cells was indistinguishable from that of wild-type virus. The adsorption of these mutants was, however, much more sensitive than that of wild-type virus to competing heparin. Furthermore, while attachment of wild-type virus to MDBK cells led to a rapid loss of sensitivity to heparin, this was not the case with PrV2, which could be displaced from the cell surface by heparin after it had attached to the cells. We conclude that glycoprotein gIII is involved in two distinct steps of virus attachment and that the second of these steps but not the first is defective in PrV2.

Two alpha-herpesvirus strains are transported differentially in the rodent visual system.

Uptake and transneuronal passage of wild-type and attenuated strains of a swine alpha-herpesvirus (pseudorabies [PRV]) were examined in rat visual projections. Both strains of virus infected subpopulations of retinal ganglion cells and passed transneuronally to infect retino-recipient neurons in the forebrain. However, the location of infected forebrain neurons varied with the strain of virus. Intravitreal injection of wild-type virus produced two temporally separated waves of infection that eventually reached all known retino-recipient regions of the central neuraxis. By contrast, the attenuated strain of PRV selectively infected a functionally distinct subset of retinal ganglion cells with restricted central projections. The data indicate that projection-specific groups of ganglion cells are differentially susceptible to the two strains of virus and suggest that this sensitivity may be receptor mediated.

Effect of brefeldin A on alphaherpesvirus membrane protein glycosylation and virus egress.

In this work we used brefeldin A (BFA), a specific inhibitor of export to the Golgi apparatus, to study pseudorabies virus viral glycoprotein processing and virus egress. BFA had little effect on initial synthesis and cotranslational modification of viral glycoproteins in the endoplasmic reticulum (ER), but it disrupted subsequent glycoprotein maturation and export. Additionally, single-step growth experiments demonstrated that after the addition of BFA, accumulation of infectious virus stopped abruptly. BFA interruption of virus egress was reversible. Electron microscopic analysis of infected cells demonstrated BFA-induced disappearance of the Golgi apparatus accompanied by a dramatic accumulation of enveloped virions between the inner and outer nuclear membranes and also in the ER. Large numbers of envelope-free capsids were also present in the cytoplasm of all samples. In control samples, these capsids were preferentially associated with the forming face of Golgi bodies and acquired a membrane envelope derived from the trans-cisternae. Our results are consistent with a multistep pathway for envelopment of pseudorabies virus that involves initial acquisition of a membrane by budding of capsids through the inner leaf of the nuclear envelope followed by deenvelopment and release of these capsids from the ER into the cytoplasm in proximity to the trans-Golgi. The released capsids then acquire a bilaminar double envelope containing mature viral glycoproteins at the trans-Golgi. The resulting double-membraned virus is transported to the plasma membrane, where membrane fusion releases a mature, enveloped virus particle from the cell.

The putative cytoplasmic domain of the pseudorabies virus envelope protein gIII, the herpes simplex virus type 1 glycoprotein C homolog, is not required for normal export and localization.

Glycoprotein gIII of pseudorabies virus is a member of a conserved gene family found in at least seven diverse herpesviruses. We report here that the putative cytoplasmic domain of gIII is not required for transport to the cell surface and, unlike the prototype domain from herpes simplex virus type 1 glycoprotein C, is not required for stable membrane anchoring. Furthermore, this domain does not appear to be essential for incorporation of the glycoprotein into virions.

Neurotropic properties of pseudorabies virus: uptake and transneuronal passage in the rat central nervous system.

Uptake, replication, and transneuronal passage of a swine neurotropic herpesvirus (pseudorabies virus, PRV) was evaluated in the rat CNS. PRV was localized in neural circuits innervating the tongue, stomach, esophagus and eye with light microscopic immunohistochemistry. In each instance, the distribution of PRV-immunoreactive neurons was entirely consistent with that observed following injection of cholera toxin-horseradish peroxidase conjugate (CT-HRP). Injections of the tongue resulted in retrograde transport of PRV and CT-HRP to hypoglossal motor neurons, while preganglionic neurons in the dorsal motor vagal nucleus or somatic motor neurons in the nucleus ambiguus were labeled following injections of the stomach or esophagus, respectively. At longer times after infection, viral antigens were found in astrocytes adjacent to infected neurons and their efferent axons and second-order neuron labeling became apparent. The distribution of second-order neurons was also entirely dependent upon the site of PRV injection. Following tongue injection, second-order neurons were observed in the trigeminal complex, the brain-stem tegmentum and in monoaminergic cell groups. Injection of the stomach or esophagus led to second-order neuron labeling confined to distinct subdivisions of the neucleus of the solitary tract and monoaminergic cell groups. Comparative quantitative analysis of the number of PRV immunoreactive neurons present in the diencephalon and brain stem following injection of virus into both the eye and stomach musculature of the same animal demonstrated that retrograde transport of PRV from the viscera was more efficient and occurred at a much faster rate than anterograde transport of virus. These data demonstrate projection-specific transport of PRV in the nervous system and provide further insight into the means through which this neurotropic virus infects the nervous system.

The export pathway of the pseudorabies virus gB homolog gII involves oligomer formation in the endoplasmic reticulum and protease processing in the Golgi apparatus.

The pseudorabies virus gII gene shares significant homology with the gB gene of herpes simplex virus type 1. Unlike gB, however, gII is processed by specific protease cleavage events after the synthesis of its precursor. The processed forms are maintained in an oligomeric complex that includes disulfide linkages. In this report, we demonstrate the kinetics of modification, complex formation, and subsequent protease processing. In particular, we suggest that gII oligomer formation in the endoplasmic reticulum is an integral part of the export pathway and that protease cleavage occurs only after oligomers have formed. Furthermore, through the use of glycoprotein gene fusions between the gIII glycoprotein and the gII glycoprotein genes of pseudorabies virus, we have mapped a functional cleavage domain of gII to an 11-amino-acid segment.

Replacement of the pseudorabies virus glycoprotein gIII gene with its postulated homolog, the glycoprotein gC gene of herpes simplex virus type 1.

gIII, the major envelope glycoprotein of pseudorabies virus (PRV), shares approximately 20% amino acid similarity with glycoprotein gC of herpes simplex virus type 1 (HSV-1) and HSV-2. We describe here our first experiments on the potential conservation of function between these two genes and gene products. We constructed PRV recombinants in which the gIII gene and regulatory sequences have been replaced with the entire HSV-1 gC gene and its regulatory sequences. The gC promoter functions in the PRV genome, and authentic HSV-1 gC protein is produced, albeit at a low level, in infected cells. The gC protein is present at the cell surface but cannot be detected in the PRV envelope.

The gene encoding the gIII envelope protein of pseudorabies virus vaccine strain Bartha contains a mutation affecting protein localization.

Pseudorabies virus (PRV) vaccine strain Bartha has a diminished capacity to cause disease and harbors a variety of mutations affecting virulence. It has been reported that PRV Bartha produces virions with reduced amounts of the major envelope glycoprotein gIII. One hypothesis was that this phenotype was due to reduced expression of the gIII gene. In this report, we demonstrate that the reduced amount of gIII in virions was not mediated at the level of transcription, but rather reflected a defect in protein localization. We describe experiments with gene replacement technology to prove that the expression defect was closely linked to the gIII gene itself. Using pulse-chase experiments, we found a defect similar to that observed for certain signal sequence mutations of PRV Becker gIII. The Bartha gIII protein was translated, but was inefficiently introduced into the membrane protein export pathway. Consequently, only a fraction of the primary Bartha gIII translation product was glycosylated and matured. The remaining fraction stayed presumably in the cytoplasm, where it never became glycosylated or inserted into cell or virus membranes. The result was that Bartha-infected cells produced virions with reduced amounts of gIII in their envelopes. Comparison of the DNA sequence of the promoter and amino-terminal coding regions of Becker and Bartha gIII genes revealed a single base pair difference in Bartha, changing codon 14 of the signal sequence from a leucine (CTC) to a proline (CCC) codon. We suggest that the signal sequence mutation is responsible for the apparent reduced expression phenotype of this attenuated strain. This mutation represents, to our knowledge, the first reported natural signal sequence mutation in a herpesvirus glycoprotein.

A herpesvirus vector for expression of glycosylated membrane antigens: fusion proteins of pseudorabies virus gIII and human immunodeficiency virus type 1 envelope glycoproteins.

We describe experiments using the swine herpesvirus, pseudorabies virus (PRV), as a vector for expression of hybrid membrane protein genes. In particular, we present the construction and analysis of three infectious PRV mutants expressing chimeric viral membrane proteins composed of portions of the PRV envelope glycoprotein gIII and of the human retrovirus, human immunodeficiency virus type 1 (HIV-1), envelope glycoproteins gp120 and gp41. All of the chimeric genes contain the transcription control sequences and the first 157 codons of PRV gIII (known to contain signals sufficient for efficient export of the encoded peptide out of the cell) fused to different regions of the HIV-1 envelope. The mutant viruses express novel glycosylated fusion proteins that are immunoprecipitated by polyvalent sera specific for gIII, as well as acquired immunodeficiency syndrome patient sera. The levels of expression are lower than expected due primarily to instability or altered processing of the hybrid mRNA. We could not detect cleavage of chimeric proteins carrying the gp120-gp41 protease processing site. The use of localization signals contained within herpesvirus membrane proteins to direct chimeric proteins to desired cellular locations is discussed.

An amino-terminal deletion mutation of pseudorabies virus glycoprotein gIII affects protein localization and RNA accumulation.

We have constructed a pseudorabies virus mutant that contains virtually a complete deletion of the predicted signal sequence coding region for a nonessential envelope glycoprotein, gIII. No signal sequence mutants have been reported previously for a herpesvirus glycoprotein. Through endoglycosidase treatments and pulse-chase analysis, we have determined that the mutant gIII protein is not posttranslationally modified like the wild-type polypeptide, but rather is present as a single, stable species within the infected cell. The mutant polypeptide cannot be detected in the virus envelope, nor is it aberrantly localized to the tissue culture medium. Immunofluorescence studies have indicated that the mutant protein also is not localized to the surfaces of infected cells. In addition, Northern (RNA) and slot blot analyses, as well as in vitro translation experiments using infected-cell cytoplasmic RNA, have indicated that the mutant gIII allele is expressed at lower levels than the wild-type gene is. This is despite the fact that no alterations have been made upstream of the gIII coding sequence. From these results, it appears that the first 22 amino acids of the wild-type gIII protein define a necessary signal peptide that is responsible for at least the correct initiation of translocation and subsequent glycosylation of the gIII envelope glycoprotein within infected cells.

Pseudorabies virus glycoprotein gIII is required for efficient virus growth in tissue culture.

Glycoprotein gIII of pseudorabies virus is a major antigen found in the envelopes of virus particles as well as in and on the surfaces of infected cells. It is not an essential gene product for virus growth in tissue culture. In this report, we provide evidence that, although it is not essential, the gIII protein is required for efficient virus growth and that gIII mutants are quickly outgrown by wild-type virus in mixed infections.

Analysis of pseudorabies virus glycoprotein gIII localization and modification by using novel infectious viral mutants carrying unique EcoRI sites.

We have constructed two pseudorabies virus (PRV) mutants, each with a unique EcoRI restriction site in the nonessential gIII envelope glycoprotein gene. Since no natural PRV isolate has been reported to contain EcoRI sites, the isolation and single-step growth curve analysis of these mutants established that PRV can carry such a site with little ill effect in tissue culture. Virus carrying these defined mutations produced novel gIII proteins that enabled us to begin functional assignment of protein localization information within the gIII gene. Specifically, one viral mutant contained an in-frame synthetic EcoRI linker sequence that was flanked on one side by the first one-third of the gIII gene and on the other side by the last one-third of the gene. The resulting protein lacked the middle one-third of the parental species, including five of eight putative N-linked glycosylation signals, but was still glycosylated and found in enveloped virions; it was not secreted into the medium. A second viral mutant contained an in-frame synthetic EcoRI linker sequence that additionally specified a nonsense codon at position 158, producing a gIII protein that was glycosylated and secreted into the medium; the fragment was not found in enveloped virions. By endoglycosidase and pulse-chase analyses, we established a precursor-product relationship between the various forms of gIII expressed in the parental and mutant strains, and perhaps determined certain features of the gIII protein that are required for its efficient export within the cell.

The pseudorabies virus gII gene is closely related to the gB glycoprotein gene of herpes simplex virus.

We have looked for conserved DNA sequences between four herpes simplex virus type 1 (HSV-1) glycoprotein genes encoding gB, gC, gD, and gE and pseudorabies virus (PRV) DNA, HSV-1 DNA fragments representing these four glycoprotein-coding sequences were hybridized to restriction enzyme fragments of PRV DNA by the Southern blot procedure. Specific hybridization was observed only when HSV-1 gB DNA was used as probe. This region of hybridization was localized to a 5.2-kilobase (kb) region mapping at approximately 0.15 map units on the PRV genome. Northern blot (RNA blot) analysis, with a 1.2-kb probe derived from this segment, revealed a predominant hybridizing RNA species of approximately 3 kb in PRV-infected PK15 cells. DNA sequence analysis of the region corresponding to this RNA revealed a single large open reading frame with significant nucleotide homology with the gB gene of HSV-1 KOS 321. In addition, the beginning of the sequenced PRV region also contained the end of an open reading frame with amino acid homology to HSV-1 ICP 18.5, a protein that may be involved in viral glycoprotein transport. This sequence partially overlaps the PRV gB homolog coding sequence. We have shown that the PRV gene with homology to HSV-1 gB encoded the gII glycoprotein gene by expressing a 765-base-pair segment of the PRV open reading frame in Escherichia coli as a protein fused to beta-galactosidase. Antiserum, raised in rabbits, against this fusion protein immunoprecipitated a specific family of PRV glycoproteins of apparent molecular mass 110, 68, and 55 kilodaltons that have been identified as the gII family of glycoproteins. Analysis of the predicted amino acid sequence indicated that the PRV gII protein shares 50% amino acid homology with the aligned HSV-1 gB protein. All 10 cysteine residues located outside of the signal sequence, as well as 4 of 6 potential N-linked glycosylation sites, were conserved between the two proteins. The primary protein sequence for HSV-1 gB regions known to be involved in the rate of virus entry into the cells and cell-cell fusion, as well as regions known to be associated with monoclonal antibody resistance, were highly homologous with the PRV protein sequence. Furthermore, monospecific antibody made against PRV gII immunoprecipitated HSV-1 gB from infected cells. Taken together, these findings suggest significant conservation of structure and function between the two proteins and may indicate a common evolutionary history.

Pseudorabies virus gene encoding glycoprotein gIII is not essential for growth in tissue culture.

We have established that in the Becker strain of pseudorabies virus (PRV), the glycoprotein gIII gene is not essential for growth in cell culture. This was accomplished by construction and analysis of viral mutants containing two defined deletion mutations affecting the gIII gene. These mutations were first constructed in vitro and introduced into Escherichia coli expression plasmids to verify structure and protein production. Each mutation was then crossed onto PRV by cotransfection of plasmid DNA and parental viral DNA by using gIII-specific monoclonal antibodies as selective and screening reagents. One resultant virus strain, PRV-2, contained an in-frame deletion of a 402-base-pair (bp) SacI fragment contained within the gIII gene. Another virus strain, PRV-10, contained a deletion of a 1,480-bp XhoI fragment removing 230 bp of the upstream, putative transcriptional control sequences and 87% of the gIII coding sequence. The deletion mutants were compared with parental virus by analysis of virion DNA, gIII specific RNA, and proteins reacting with gIII specific antibodies. Upon infection of PK15 cells, the deletion mutants did not produce any proteins that reacted with two gIII specific monoclonal antibodies. However, two species of truncated glycosylated proteins were observed in PRV-2 infected cells that reacted with antiserum raised against bacterially produced gIII protein. PRV-10 produced no detectable gIII-specific RNA or protein. PRV-10 could be propagated without difficulty in tissue culture. Virus particles lacking gIII were indistinguishable from parental PRV virus particles by analysis of infected-cell thin sections in the electron microscope. We therefore conclude that expression of the gIII gene was not absolutely essential for PRV growth in tissue culture.

Characterization of a pseudorabies virus glycoprotein gene with homology to herpes simplex virus type 1 and type 2 glycoprotein C.

A pseudorabies virus (Becker strain) glycoprotein gene was located in the UL region at map position 0.40. The gene was identified by using open reading frame Escherichia coli plasmid expression vectors and specific antibody reagents. A 1.55-kilobase unspliced transcript from the gene was detected in pseudorabies virus-infected tissue culture cells. The DNA sequence revealed a single open reading frame of 1,437 base pairs encoding 479 amino acids. The predicted primary translation product has a molecular weight of 50,860 and contains features of a typical herpesvirus glycoprotein. An E. coli expression plasmid was constructed that contained essentially all of the open reading frame for this gene. Antibodies raised in rabbits against the protein expressed in bacteria by this plasmid immunoprecipitated pseudorabies virus-specific glycoproteins of 92,000 and 74,000 daltons from infected cell extracts. It is likely that these two forms represent different glycosylation states of the protein.