Mutations in the UL53 gene of HSV-1 abolish virus neurovirulence to mice by the intracerebral route of infection

Pathologic and virologic characterization of neuroinvasion by HSV-2 in a mouse encephalitis model

Herpes simplex virus type 2 (HSV-2), a ubiquitous human pathogen associated with genital infections, is neurotropic. It establishes latent infections in local dorsal root ganglia from which it reactivates causing recurrent lesions and frequent episodes of viral shedding. Herpes simplex virus type 2 can also be transmitted from mother to child during birth, causing major neonatal complications including encephalitis. Animal models of HSV-2 genital infection are well described and used for testing of therapies; little is known about animal models of HSV-2-induced encephalitis. We analyzed the pathologic and immunohistochemical features of the nasal rostrum and brain tissue and correlated them with viral distribution in a mouse model of HSV-2 encephalitis induced by intranasal infection and examined viral replication in the brain tissue using quantitative polymerase chain reaction and traditional plaque assay. Our results suggest that the primary route for HSV-2 neuroinvasion after intranasal infection is via the trigeminal pathway, ultimately leading to infection of the brainstem and meningoencephalitis.

ICAM-5 modulates cytokine/chemokine production in the CNS during the course of herpes simplex virus type 1 infection

Chemokines are important in HSE development in the CNS but underlying regulatory events are unknown. Two-hybrid binding assays identified that intercellular adhesion molecule 5 (ICAM-5), an immune modulator in the CNS, interacted with neurovirulence factor, UOL, of HSV-1. Viral load and interleukin levels were similar in UOL deletion virus (DeltaUOL), and wild type virus infected mouse brains. However, higher numbers of lymphocytes, but unaltered soluble ICAM-5 and chemokine levels were detected in DeltaUOL infected mouse brains. In contrast, lower lymphocyte numbers, reduced soluble ICAM-5, and higher chemokine levels were detected in wild type virus infected brains. Our results suggest that ICAM-5 plays a critical role in modulating chemokine production in the CNS.

Functional and physical interactions of the herpes simplex virus type 1 UL20 membrane protein with glycoprotein K

Herpes simplex virus type 1 glycoprotein K (gK) and the UL20 protein (UL20p) are coordinately transported to the trans-Golgi network (TGN) and cell surfaces and are required for cytoplasmic virion envelopment at the TGN. In addition, cell surface expression of gK and UL20p is required for virus-induced cell fusion. Previously, confocal microscopy colocalization and intracellular transport experiments strongly suggested direct protein-protein interactions between gK and UL20p. Direct protein-protein interactions between gK and UL20p were demonstrated through reciprocal coimmunoprecipitation experiments, as well as with glutathione S-transferase (GST) pull-down experiments. A fusion protein consisting of the amino-terminal 66 amino acids of UL20p fused in-frame with GST was expressed in Escherichia coli and purified via glutathione column chromatography. Precipitation of GST-UL20p from mixtures of GST-UL20p fusion protein with cellular extracts containing gK specifically coprecipitated gK but not other viral glycoproteins. The purified UL20p-GST fusion protein reacted with all gK-associated protein species. It was concluded that the amino terminus of UL20p, most likely, interacted with gK domain III, which is predicted to lie intracellularly. UL20p-gK domain-specific interactions must serve important functions in the coordinate transport of UL20p and gK to the TGN, because retention of UL20p in the endoplasmic reticulum (ER) via the addition of an ER retention signal at the carboxyl terminus of UL20p forced the ER retention of gK and drastically inhibited intracellular virion envelopment and virus-induced cell fusion.

Intranasal herpes simplex virus type 2 inoculation causes a profound thymidine kinase dependent cerebral inflammatory response in the mouse hindbrain

The herpes simplex virus (HSV) has the ability to replicate in the central nervous system (CNS), which may cause fatal encephalitis. The present study investigated the activity of the nuclear factor kappa B (NF-kappa B) and the pattern of cytokine/chemokine gene expression across the brain of HSV-infected mice and the role of the viral thymidine kinase (TK) in mediating these effects. Mice were killed 1-8 days after intranasal inoculation with either HSV-2 TK-competent or TK-deficient clinical isolates. Animals infected with the TK-competent virus exhibited first signs of infection at day 5 postinoculation, whereas severe signs of sickness were observed between day 6 and 8. A robust hybridization signal was found in the brain of these animals for the gene encoding the inhibitory factor kappa B alpha (I kappa B alpha, index of NF-kappa B activity), toll-like receptor 2 (TLR2), tumour necrosis factor alpha (TNF-alpha) and monocyte chemoattractant protein-1 (MCP-1) in numerous regions of the pons and medulla. The levels of expression of these genes increased 4 days after the inoculation and peaked at day 6 within the endothelium of the brain capillaries and cells of myeloid origin. A robust signal for the TK gene and its encoding protein was detected selectively within the regions that exhibited expression of the immune molecules. In contrast, animals that received the TK-deficient virus did not show any signs of sickness or cerebral inflammation or HSV replication within the cerebral tissue. The present data provide clear evidence that HSV-2 has the ability to trigger a profound inflammatory response in a pattern that follows the viral TK-dependent HSV replication in neurons. Such neurovirulence occurring in the hindbrain is proposed here to be directly responsible for neurodegeneration and to lead to the cerebral innate immune response, which in turn could play a key role in fatal HSV-2-induced encephalitis.

Characterization of strain HSZP of herpes simplex virus type 1 (HSV1)

The genetic background of HSZP virus, an HSV1 strain with extensive passage history, was analyzed by parallel comparative sequencing of four relevant genes (UL27/gB, UL41/vhs, UL44/gC and UL53/gK) of HSZP and additional three selected viruses [strains ANGpath, strains KOS(a) and KOS(b) and the prototype strain 17]. Mutation at position 858 (His for Arg) in gB of HSZP was found to be responsible for giant cell formation (syn3gB mutation) similarly as the 855 mutation (Val for Ala) in the gB of ANGpath. No syn1gK mutations were detected in the UL53 gene either of HSZP or of ANGpath viruses. The reduced virulence of HSZP for adult mice after peripheral inoculation, similarly as that of KOS virus, seems to be related (at least in part) to numerous mutations in the gB ectodomain. Of these, two mutations located in the antigenic domain IV were the same in gBHSZP as well as in gBKOS (at amino acids 59 and 79), at least two (amino acids 313 and 553) were specific for gBKOS, while one mutation (Ser for Ala at position 108) was specific for gBHSZP. The abolished shutoff function of the HSZP virus was related to at least four out of six specific mutations seen in the vhs polypeptide (vhsHSZP) encoded by the UL41 gene, of which three (amino acids 374, 386, 392) were clustered in the semiconservative box A of vhsHSZP (the truncation of which abrogates the inhibition provided by this protein) and one mutation (at amino acid 18) was situated in the highly conservative locus I of vhsHSZP. In addition, the two vhsKOS specific mutations (amino acids 19 and 317) not found in vhsHSZP, enhanced the early host shutoff function of the vhsKOS protein. Finally, gCHSZP had two specific mutations (amino acids 137 and 147) located in the antigenic domain II of gC, which is responsible for binding of HSV1 virions to the glycosoaminoglycan (GAG) receptor. When expressed in Sf21 cells using the recombinant baculovirus system (Bac-to-Bac), gCHSZP and gCKOS showed no essential antigenic differences.

The genome of cowpox virus contains a gene related to those encoding the epidermal growth factor, transforming growth factor alpha and vaccinia growth factor

Cowpox virus (CPV) is a member of the Orthopoxvirus genus and has the genetic capacity to encode a multitude of genes that interfere with the host inflammatory and immune response or modulate the physiological state of infected and non-infected cells. Among these CPV factors are receptors homologous to interferon and tumor necrosis factor receptors and also a viral cellular serine-proteinase analog. Here we describe the detection of a CPV gene that encodes a protein homologous to epidermal growth factor, transforming growth factor alpha and poxvirus growth factors, such as the vaccinia growth factor (VGF). The VGF and other poxvirus growth factors are produced early in the infection and are secreted into the medium where they bind to the EGF receptors, generating mytotic responses. The cowpox growth factor (CGF) gene was detected in three copies on the virus genome by PCR, and by northern and southern blot hybridization using VGF nucleotide sequences as primers and probes. The CPV gene has a strong nucleotide and predicted amino acid similarity with VGF, and is also produced early in the infection.

Glycoprotein K of herpes simplex virus: a transmembrane protein encoded by the UL53 gene which regulates membrane fusion

Glycoprotein K (gK) encoded by the UL53 gene is the ninth out of eleven HSV glycoproteins (gps). The precursor gK (pgK) is a transmembrane protein with four hydrophobic domains, which consists of 338 amino acids. The UL53 gene has two initiation codons: the upper overlaps with the UL52 ORF, while the lower is located 55 codons downstream and specifies a truncated precursor of the gK polypeptide. The UL53 gene and the upstream located UL52 gene have a common polyadenylation signal downstream from the UL53 stop codon so that the UL53 mRNA is completely nested within the UL52 transcript. The syn1 mutations in several KOSsyn mutants and in the MPsyn virus, which had been fine mapped to DNA coordinates 0.735-0.740, were later on located to the UL53 gene, especially to its portion which specifies the first 120 amino acids (aa) from the N-terminus (most frequently residue 40) and to a less precisely defined locus between aa 301-310 (close to the C-terminus). Point mutations in the N-terminal ectodomain of gK, which are related to syn formation, impair the putative ability of this region to down-regulate membrane fusion. The two N-glycosylated mannose core oligosaccharides are attached to the Asn residues of the gK polypeptide at positions 48 and 58, respectively. In infected cells, gK is localized mainly in the nuclear and endoplasmic reticulum (ER) membranes. It is not clear, whether gK becomes incorporated into the envelope of mature HSV particles. Studies with the insertion/deletion gK mutants showed the importance of gK for capsid envelopment, for the transportation and egress or virions from infected cells. It seems that gK has an essential role in virion egress, even though this glycoprotein acts in accord with gH and with another membrane protein encoded by the UL20 gene.

Expression of the enhanced green fluorescent protein by herpes simplex virus type 1 (HSV-1) as an in vitro or in vivo marker for virus entry and replication

Glycoprotein K (gK) is involved in membrane fusion phenomena during infectious virus production and egress and is an important determinant for neurovirulence. To assess better the in vitro and in vivo roles of gK in virus replication, a recombinant virus was constructed expressing an engineered enhanced green fluorescent protein (EGFP) under the control of the human cytomegalovirus immediate early gene promoter (HCMV-IEP) inserted in place of the gK gene. The EGFP gene insertion was confirmed by diagnostic polymerase chain reaction (PCR), and the presence of the EGFP protein was detected by western immunoblot analysis using anti-GFP monoclonal antibody. Fluorescence microscopy revealed that virus infected cells emitted bright fluorescence when examined using filters for fluorescein. Fluorescence emission was detected as early as 4 h post-infection. Fluorescence intensity increased over time and was stable at late times after infection at which point viral plaques continued to emit bright green fluorescence. The amount of fluorescence emitted by virus infected Vero cells was monitored by fluorescence cytometry using a FACS cytometer. At an MOI of 3, all infected cells emitted strong green fluorescence as quantified by cytometry at 48 h post-infection. The deltagK-EGFP expressing recombinant virus will enable the determination of the role of gK in virus entry and egress as well as the role of gK in the molecular pathogenesis of herpes simplex virus type 1 (HSV-1).

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.

Analysis of the transcription pattern of HSV-1 UL52 and UL53 genes

The UL52 and UL53 genes of herpes simplex virus type-1 are both located in the BamHI-L DNA fragment, with an overlap of 14 amino acids. An RNase protection experiment was designed to determine the 5' termini of both the UL52 and UL53 mRNAs. The 5' end of the UL52 mRNA was found to be located 100 bp upstream of its ATG initiation codon. Surprisingly, the 5' terminus of the UL53 gene was found to be downstream of its putative initiation codon. Therefore, it was suggested that the translation of the UL53 open reading frame (ORF) starts at an internal initiation codon that is located 55 codons downstream of the putative one. A hybrid selection experiment was performed in which the UL53-specific mRNA was selected from BSC-1 cells infected with HSV-1 KOS and translated in vitro. The translation product of the UL53 message was found to be 32 kD (shorter than the original 37.5 kD ORF). The size of the protein obtained corresponds with the expected translation product starting at the downstream initiation codon. Analysis of the sequence upstream of this initiation codon reveals the presence of a promotor sequence. Therefore, we suggest that the UL53 protein is 54 amino acids shorter than was previously suggested and is located at coordinates 112,341-113,193.

Herpes simplex virus type 1 (HSV-1) UL56 gene is involved in viral intraperitoneal pathogenicity to immunocompetent mice

A comparison of the pathogenicity in mice of the recombinant herpes simplex virus type 1 (HSV-1) strain HSV-1-M-LacZ, in which the UL56 gene has been deleted, was made with its parental strain F, following infection in different mouse strains. The polymerase chain reaction (PCR) technique was used to study the migration of virus DNA in the mouse model. Tissues from adult mice infected intraperitoneally (IP) with one of three HSV-1 strains (F, HFEM or HSV-1-LacZ) were examined for the presence of viral DNA. DNA of the pathogenic strain F was detected in the adrenal glands, spinal cord, brain, liver and pancreas. DNA of HSV-1-M-LacZ was detected in the same tissues. However, DNA of the apathogenic strain HFEM was detected transiently (on days 2 and 3 p.i., but not days 1, 5 or 7), only in the adrenal glands and no viral DNA was detected in any of the other tissues. HSV-1 pathogenic strains injected intraperitoneally into newborn mice (7 days old) killed most of the mice. In the surviving mice viral DNA of the three virus strains was found in peritoneal exudate cells (PEC), adrenal glands, spinal cord, liver and spleen. It was found that HSV-1-M-LacZ, which lacks the UL56 gene, resembled in pathogenicity to the newborn mice the pathogenic HSV-1 strains F and KOS. The PCR technique was used to trace viral DNA in tissues of the mice which survived HSV-1 infection at 7 weeks of age. Only HSV-1 (KOS) DNA was detected in the pancreas. The brains of these mice did not contain viral DNA. It is suggested that HSV-1 DNA may reside in surviving HSV-1- infected newborn mice in a "latent" state in nonneural tissues.