Varicella-zoster virus (VZV) is considered to be one of the most genetically stable of all the herpesviruses.Yet two VZV strains with a D150N missense mutation within the gE glycoprotein were isolated in North America in 1998 and 2002. The mutant strains have an accelerated cell spread phenotype, which distinguishes them from all wild-type and laboratory viruses. Since the VZV genome contains 70 additional open reading frames (ORFs), the possibility existed that the phenotypic change was actually due to an as-yet-undiscovered mutation or deletion elsewhere in the genome. To exclude this hypothesis, the entire genomes of the two mutant viruses were sequenced and found to contain 124,883 (VZV-MSP) and 125,459 (VZV-BC) nucleotides. Coding single-nucleotide polymorphisms (SNPs) were identified in 14 ORFs. One missense mutation was discovered in gH, but none was found in gB, gI, gL, or gK. There were no coding SNPs in the major regulatory protein ORF 62. One polymorphism was discovered which could never have been anticipated based on current knowledge of herpesvirus genomics, namely, the origins of replication differed from those in the prototype strain but not in a manner expected to affect cell spread. When the two complete mutant VZV sequences were surveyed in their entirety, the most reasonable conclusion was that the increased cell spread phenotype was dependent substantially or solely on the single D150N polymorphism in glycoprotein gE. The genomic results also expanded the evolutionary database by identifying which VZV ORFs were more likely to mutate over time.
In the course of examining the trafficking pathways of varicella-zoster virus (VZV) glycoproteins gE, gI, gH, and gB, we discovered that all four are synthesized within 4 to 6 h postinfection (hpi) in cultured cells. Thereafter, they travel via the trans-Golgi network to the outer cell membrane. When we carried out a similar analysis on VZV gC, we observed little gC biosynthesis in the first 72 hpi. Further examination disclosed that gC was present in the inocula of infected cells, but no new gC biosynthesis occurred during the first 24 to 48 h thereafter, during which time new synthesis of gE, gH, and major capsid protein was easily detectable. Similarly, delayed gC biosynthesis was confirmed with three different VZV strains and two different cell lines. Bioinformatics analyses disclosed the presence of PBX/HOX consensus binding domains in the promoter/ enhancer regions of the genes for VZV gC and ORF4 protein (whose orthologs transactivate gC in other herpesviruses). Bioinformatics analysis also identified two HOXA9 activation regions on ORF4 protein. Treatment of infected cultures with chemicals known to induce the production of PBX/HOX transcription proteins, namely, hexamethylene bisacetamide (HMBA) and retinoic acid, led to more rapid gC biosynthesis. Immunoblotting demonstrated a fivefold increase in the HOXA9 protein after HMBA treatment. In summary, these results documented that gC was not produced during early VZV replication cycles, presumably related to a deficiency in the PBX/HOX transcription factors. Furthermore, these results explain the apparent spontaneous loss of VZV gC in some passaged viruses, as well as other anomalous gC results.Varicella-zoster virus (VZV) is a very cell-associated virus in cell culture. In addition, the infectivity titers are extremely low, usually less than 1,000,000 U per 25-cm 2 monolayer. Further, the virions produced in cell culture have an aberrant appearance. Explanations for these observations are a subject of continuing research. To this end, we have been investigating the biosynthesis and maturation of several VZV structural glycoproteins found in the envelope of the virion, especially the predominant gE/gI complex. These two glycoproteins are synthesized in the Golgi and then traffic through the trans-Golgi network en route to the outer plasma membrane within the expected 12-h replication cycle of an alphaherpesvirus. After endocytosis via their tyrosine-and dileucine-based motifs, they travel back to the trans-Golgi network (12). At this location, the glycoproteins appear to be incorporated into the virion assembly vacuoles. Two other major VZV glycoproteins, gH and gB, have similar endocytosis motifs and similar trafficking profiles.During the glycoprotein trafficking studies, VZV gC was used as a control because there are no obvious trafficking motifs in its short cytoplasmic tail (20). There have been clues that gC is important for virion production. The severe combined immunodeficient (SCID) mouse has become an important animal model for the investigation...
Because of its very low titer, varicella-zoster virus (VZV) infectivity is usually transferred by passage of trypsin dispersed infected cells. Previously, we observed that gC biosynthesis was markedly delayed in monolayers inoculated with cell free virus. In this report, we investigated the kinetics of gC expression in more detail and included studies of monolayers inoculated with trypsin dispersed infected cells, the more traditional method of VZV infection. Extensive imaging analyses disclosed that gC was detectable in some inoculum cells, but little gC biosynthesis occurred during the first 48 hpi in the newly infected underlying monolayer. In contrast, during the first 24–48 hpi, expression of VZV gE and gB was easily detectable. Using real-time RT-PCR, we found a delay in accumulation of VZV gC transcripts that paralleled the delay in expression of VZV gC protein. Treatment with hexamethylene bisacetamide (HMBA) increased expression of both gC protein and gC mRNA. HMBA treatment also increased virus titer by 4-fold, but paradoxically reduced plaque size in the titration assay. Finally, we examined skin vesicles from cases of chickenpox and zoster in humans and observed abundant amounts of gC expression. In short, this report documents an unexpected delay in both gC mRNA and protein production under all conditions of VZV infection of cultured cells.
ORF47, a serine/threonine protein kinase encoded by varicella-zoster virus (VZV), has often been compared to the ubiquitous cellular kinase, casein kinase II (CKII). However, no direct comparison of the two protein kinases has been carried out. Herein, we show that the ORF47 kinase was resistant to heparin, while CKII activity is profoundly inhibited by the acidic molecule in vitro. ORF47 required the presence of polyamines (aliphatic, positively-charged molecules) for in vitro activity. When polyamines were depleted from MeWo cells prior to VZV infection by pretreatment with D,L-alpha-difluoromethylornithine, VZV replication was reduced by 80%. Finally, the substrate specificity of the ORF47 kinase was defined using an in vitro assay. The ORF47 kinase phosphorylated maltose-binding protein, the mouse IgG2A heavy chain, the rabbit IgG heavy chain, casein, VZV ORF62, and VZV ORF63. The ORF47 kinase failed to phosphorylate an ORF62 truncation mutant, glutathione-S-transferase, or VZV gB. In contrast, CKII weakly phosphorylated VZV gB in vitro. By analyzing the sequences of these substrates, the minimal ORF47 consensus sequence was deduced to be the following motif: S/T-X-D/E-D/E, with a marked preference for additional acidic amino acids in the -1 and +1 position.
The complete DNA sequences of wild-type and vaccine strains of varicella-zoster virus have been published and listed in GenBank. In this comparative genomic analysis, the sequences of the 9 glycoprotein open reading frames (ORFs) were compared. They included gE (ORF68), gI (ORF 67), gC (ORF14), gH (ORF37), gL (ORF60), gB (ORF31), gK (ORF5), gM (ORF50), and gN (ORF8 or ORF9A). After realignment on the basis of newer data, the corrected gB sequence was lengthened to include 931 residues. The data showed that there were glycoprotein polymorphisms that differentiated North American/European strains from Japanese strains-for example, an additional ATG codon in the gL of all Oka strains. Also, there were a small number of coding single-nucleotide polymorphisms present only in glycoproteins of vaccine strains. Because these changes were highly conserved, the structure of the glycoprotein was unlikely to be altered.
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