Absence or overexpression of the Varicella-Zoster Virus (VZV) ORF29 latency-associated protein impairs late gene expression and reduces VZV latency in a rodent model

Varicella-zoster virus (VZV) ORF29 encodes the viral single-stranded DNA binding protein and is expressed during latency in human ganglia. We constructed an ORF29 deletion mutant virus and showed that the virus could replicate only in cells expressing ORF29. An ORF29-repaired virus, in which ORF29 was driven by a cytomegalovirus promoter, grew to peak titers similar to those seen with the parental virus. The level of ORF29 protein in cells infected with the repaired virus was greater than that seen with parental virus. Infection of cells with either the ORF29 deletion or repaired virus resulted in similar levels of VZV immediate-early proteins but reduced levels of glycoprotein E compared to those observed with parental virus. Cotton rats infected with the ORF29 deletion mutant had a markedly reduced frequency of latent infection in dorsal root ganglia compared with those infected with parental virus (P < 0.00001). In contrast, infection of animals with the ORF29 deletion mutant resulted in a frequency of ganglionic infection at 3 days similar to that seen with the parental virus. Animals infected with the ORF29-repaired virus, which overexpresses ORF29, also had a reduced frequency of latent infection compared with those infected with parental virus (P = 0.0044). These studies indicate that regulation of ORF29 at appropriate levels is critical for VZV latency in a rodent model.     

The varicella-zoster virus (VZV) open reading frame 47 (ORF47) protein kinase is dispensable for viral replication and is not required for phosphorylation of ORF63 protein, the VZV homolog of herpes simplex virus ICP22.

To investigate the role of varicella-zoster virus (VZV) open reading frame 47 (ORF47) protein kinase during infection, a VZV mutant was generated in which two contiguous stop codons were introduced into ORF47, thus eliminating expression of the ORF47 kinase. ORF47 kinase was not essential for the growth of VZV in cultured cells, and the growth rate of the VZV mutant lacking ORF47 protein was indistinguishable from that of parental VZV. Nuclear extracts from cells infected with parental VZV contained several phosphorylated proteins which were not detected in extracts from cells infected with the ORF47 mutant. The herpes simplex virus type 1 (HSV-1) UL13 protein (the homolog of VZV ORF47 protein) is responsible for the posttranslational processing associated with phosphorylation of HSV-1 ICP22 (the homolog of VZV ORF63 protein). Immunoprecipitation of 32P-labeled proteins from cells infected with parental virus and those infected with ORF47 mutant virus yielded similar amounts of the VZV phosphoproteins encoded by ORF4, ORF62, ORF63, and ORF68 (VZV gE), and the electrophoretic migration of these proteins was not affected by the lack of ORF47 kinase. Therefore, while the VZV ORF47 protein is capable of phosphorylating several cellular or viral proteins, it is not required for phosphorylation of the ORF63 protein in virus-infected cells.     

Varicella-zoster virus (VZV) ORF17 protein induces RNA cleavage and is critical for replication of VZV at 37 degrees C but not 33 degrees C

Varicella-zoster virus (VZV) open reading frame 17 (ORF17) is homologous to herpes simplex virus (HSV) UL41, which encodes the viral host shutoff protein (vhs). HSV vhs induces degradation of mRNA and rapid shutoff of host protein synthesis. An antibody to ORF17 protein detected a 46-kDa protein in VZV-infected cells. While HSV vhs is located in virions, VZV ORF17 protein was not detectable in virions. ORF17 protein induced RNA cleavage, but to a substantially lesser extent than HSV-1 vhs. Expression of ORF17 protein did not inhibit expression from a beta-galactosidase reporter plasmid, while HSV type 1 vhs abolished reporter expression. Two VZV ORF17 deletion mutants were constructed to examine the role of ORF17 in virus replication. While the ORF17 VZV mutants grew to peak titers that were similar to those of the parental virus at 33 degrees C, the ORF17 mutants grew to 20- to 35-fold-lower titers than parental virus at 37 degrees C. ORF62 protein was distributed in a different pattern in the nuclei and cytoplasm of cells infected with an ORF17 deletion mutant at 37 degrees C compared to 33 degrees C. Inoculation of cotton rats with the ORF17 deletion mutant resulted in a level of latent infection similar to that produced by inoculation with the parental virus. The importance of ORF17 protein for viral replication at 37 degrees C but not at 33 degrees C suggests that this protein may facilitate the growth of virus in certain tissues in vivo.     

Varicella-Zoster Virus (VZV) ORF32 Encodes a Phosphoprotein That Is Posttranslationally Modified by the VZV ORF47 Protein Kinase

Varicella-zoster virus (VZV) encodes five gene products that do not have homologs in herpes simplex virus. One of these genes, VZV open reading frame 32 (ORF32), is predicted to encode a protein of 16 kDa. VZV ORF32 protein was shown to be phosphorylated and located in the cytosol of virus-infected cells. Antibody to ORF32 protein immunoprecipitated 16- and 18-kDa phosphoproteins from VZV-infected cells. Since VZV encodes two protein kinases that might phosphorylate ORF32 protein, immunoprecipitations were performed with cells infected with VZV mutants unable to express either of the viral protein kinases. Cells infected with VZV unable to express the ORF66 protein kinase contained both the 16- and 18-kDa ORF32 phosphoproteins; however, cells infected with the VZV ORF47 protein kinase mutant showed only the 16-kDa ORF32 phosphoprotein. Treatment of [³⁵S]methionine-labeled proteins with calf intestine alkaline phosphatase resulted in a decrease in size of the ORF32 proteins from 16 and 18 kDa to 15 and 17 kDa, respectively. VZV unable to express ORF32 protein replicated in human melanoma cells to titers similar to those seen with parental virus; however, VZV unable to express ORF32 was impaired for replication in U20S osteosarcoma cells. Thus, VZV ORF32 protein is posttranslationally modified by the ORF47 protein kinase. Since the VZV ORF47 protein kinase has recently been shown to be critical for replication in human fetal skin and lymphocytes, its ability to modify the ORF32 protein suggests that the latter protein may have a role for VZV replication in human tissues.     

Varicella-zoster virus glycoprotein I is essential for growth of virus in Vero cells.

Varicella-zoster virus (VZV) encodes at least six glycoproteins. Glycoprotein I (gI), the product of open reading frame 67, is a 58- to 62-kDa glycoprotein found in VZV-infected cells. We constructed two VZV gI deletion mutants. Immunoprecipitation of VZV gE from infected cells indicated that cells infected with VZV deleted for gI expressed a gE that was larger (100 kDa) than that expressed in cells infected with the parental virus (98 kDa). Cell-associated or cell-free VZV deleted for gI grew to lower titers in melanoma cells than did parental VZV. While VZV deleted for gI replicated in other human cells, the mutant virus replicated to very low titers in primary guinea pig and monkey cells and did not replicate in Vero cells. When compared with the parental virus, rescued viruses, in which the gI deletion was restored with a wild-type allele, showed a similarly sized gE and comparable growth patterns in melanoma and Vero cells. VZV deleted for gI entered Vero cells; however, viral DNA synthesis was impaired in these cells. The VZV gI mutant was slightly impaired for adsorption to human cells. Thus, VZV gI is required for replication of the virus in Vero cells, for efficient replication of the virus in nonhuman cells, and for normal processing of gE.     

Varicella-zoster virus (VZV) open reading frame 10 protein, the homolog of the essential herpes simplex virus protein VP16, is dispensable for VZV replication in vitro.

Varicella-zoster virus (VZV) open reading frame 10 (ORF10) protein in the homolog of the herpes simplex virus type 1 (HSV-1) protein VP16. VZV ORF10 transactivates the VZV IE62 gene and is a tegument protein present in the virion. HSV-1 VP16, a potent transactivator of HSV-1 immediate-early genes and tegument protein, is essential for HSV-1 replication in vitro. To determine whether VZV ORF10 is required for viral replication in vitro, we constructed two VZV mutants which were unable to express ORF10. One mutant had a stop codon after the 61st codon of the ORF10 gene, and the other mutant was deleted for all but the last five codons of the gene. Both VZV mutants grew in cell culture to titers similar to that of the parental virus. To determine whether HSV-1 VP16 alters the growth of VZV, we constructed a VZV mutant in which VP16 was inserted in place of ORF10. Using immune electron microscopy, we found that HSV-1 VP16 was present in the tegument of the recombinant VZV virions. The VZV VP16 substitution mutant produced smaller plaques and grew to a lower titer than parental virus. Thus, VZV ORF10 is not required for growth of the virus in vitro, and substitution of HSV-1 VP16 for VZV ORF10 impairs the growth of VZV.     

The varicella-zoster virus ORF66 protein induces kinase activity and is dispensable for viral replication.

Varicella-zoster virus (VZV) open reading frames (ORFs) 47 and 66 encode proteins that are homologous to a family of eukaryotic serine-threonine kinases. Prior studies showed that the VZV ORF47 protein has kinase activity in vitro and is dispensable for replication in cultured cells. To examine the role of the ORF66 protein during infection, we constructed VZV recombinants that are unable to express either the ORF66 protein (ROka 66S) or both the ORF47 and ORF66 proteins (ROka 47S/66S). VZV unable to express ORF66 grew to titers similar to those of the parental VZV (ROka) in vitro; however, VZV lacking both ORF66 and ORF47 grew to titers lower than those of ROka. Nuclear extracts from ROka 66S- or ROka 47S-infected cells showed a 48-kDa phosphoprotein(s); a phosphoprotein with a similar size was not present in nuclear extracts from ROka 47S/66S-infected cells. To determine the role of the ORF66 protein in the phosphorylation of specific VZV-encoded proteins, we immunoprecipitated known VZV phosphoproteins (ORF4, ORF62, ORF63, and ORF68 proteins) from nuclear extracts of phosphate-labeled cells infected with ROka, ROka 66S, or ROka 47S/66S. Each of the VZV phosphoproteins was phosphorylated to a similar extent in the presence or absence of either the ORF66 protein or both the ORF66 and ORF47 proteins. From these studies we conclude (i) neither ORF66 alone nor ORF66 and ORF47 in combination are essential for VZV growth in cultured cells, (ii) ORF66 either is a protein kinase or induces protein kinase activity during infection, and (iii) the VZV phosphoproteins encoded by ORF4, ORF62, ORF63, and ORF68 do not require either ORF66 alone or ORF66 and ORF47 for phosphorylation in vitro.     

Deletion of the varicella-zoster virus large subunit of ribonucleotide reductase impairs growth of virus in vitro.

Cells infected with varicella-zoster virus (VZV) express a viral ribonucleotide reductase which is distinct from that present in uninfected cells. VZV open reading frames 18 and 19 (ORF18 and ORF19) are homologous to the herpes simplex virus type 1 genes encoding the small and large subunits of ribonucleotide reductase, respectively. We generated recombinant VZV by transfecting cultured cells with four overlapping cosmid DNAs. To construct a virus lacking ribonucleotide reductase, we deleted 97% of VZV ORF19 from one of the cosmids. Transfection of this cosmid with the other parental cosmids yielded a VZV mutant with a 2.3-kbp deletion confirmed by Southern blot analysis. Virus-specific ribonucleotide reductase activity was not detected in cells infected with VZV lacking ORF19. Infection of melanoma cells with ORF19-deleted VZV resulted in plaques smaller than those produced by infection with the parental VZV. The mutant virus also exhibited a growth rate slightly slower than that of the parental virus. Chemical inhibition of the VZV ribonucleotide reductase has been shown to potentiate the anti-VZV activity of acyclovir. Similarly, the concentration of acyclovir required to inhibit plaque formation by 50% was threefold lower for the VZV ribonucleotide reductase deletion mutants than for parental virus. We conclude that the VZV ribonucleotide reductase large subunit is not essential for virus infection in vitro; however, deletion of the gene impairs the growth of VZV in cell culture and renders the virus more susceptible to inhibition by acyclovir.