Glycoprotein D of herpes simplex virus encodes a domain which precludes penetration of cells expressing the glycoprotein by superinfecting herpes simplex virus

We characterized the glycoprotein K (gK)-null herpes simplex virus type 1 [HSV-1] (KOS) ⌬gK and compared it to the gK-null virus HSV-1 F-gK␤ (L. Hutchinson et al., J. Virol. 69:5401-5413, 1995). ⌬gK and F-gK␤ mutant viruses produced small plaques on Vero cell monolayers at 48 h postinfection. F-gK␤ caused extensive fusion of 143TK cells that was sensitive to melittin, a specific inhibitor of gK-induced cell fusion, while ⌬gK virus did not fuse 143TK cells. A recombinant plasmid containing the truncated gK gene specified by F-gK␤ failed to rescue the ICP27-null virus KOS (d27-1), while a plasmid with the ⌬gK deletion rescued the d27-1 virus efficiently. ⌬gK virus yield was approximately 100,000-fold lower in stationary cells than in actively replicating Vero cells. The plaquing efficiencies of ⌬gK and F-gK␤ virus stocks on VK302 cells were similar, while the plaquing efficiency of F-gK␤ virus stocks on Vero cells was reduced nearly 10,000-fold in comparison to that of ⌬gK virus. Mutant ⌬gK and F-gK␤ infectious virions accumulated within Vero and HEp-2 cells but failed to translocate to extracellular spaces. ⌬gK capsids accumulated in the nuclei of Vero but not HEp-2 cells. Enveloped ⌬gK virions were visualized in the cytoplasms of both Vero and HEp-2 cells, and viral capsids were found in the cytoplasm of HEp-2 cells within vesicles. Glycoproteins B, C, D, and H were expressed on the surface of ⌬gK-infected Vero cells in amounts similar to those for KOS-infected Vero cells.These results indicate that gK is involved in nucleocapsid envelopment, and more importantly in the translocation of infectious virions from the cytoplasm to the extracellular spaces, and that actively replicating cells can partially compensate for the envelopment but not for the cellular egress deficiency of the ⌬gK virus.

Section: Discussionmentioning

confidence: 52%

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confidence: 99%

Herpes simplex virus type 1 glycoprotein K is not essential for infectious virus production in actively replicating cells but is required for efficient envelopment and translocation of infectious virions from the cytoplasm to the extracellular space

Jayachandra

Baghian

Kousoulas

1997

“…The mechanism of gD-mediated interference is not understood. It has been proposed that cell-associated gD interferes with a cell surface component required for viral entry or interacts with the virion itself, perhaps to disrupt interactions among the viral glycoproteins (3,4,8,11). Recently it was shown that a soluble recombinant form of gD becomes modified by the addition of mannose-6-phosphate (Man-6-P) to N-linked glycans and that this form can bind to Man-6-P receptors (2).…”

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confidence: 99%

Viral determinants of the variable sensitivity of herpes simplex virus strains to gD-mediated interference

Dean

Warner

Terhune

et al. 1995

Cells that express glycoprotein D (gD) of herpes simplex virus type 1 (HSV-1) resist infection by HSV-1 and HSV-2 because of interference with viral penetration. The results presented here show that both HSV-1 and HSV-2 gD can mediate interference and that various HSV-1 and HSV-2 strains differ in sensitivity to this interference. The relative degree of sensitivity was not necessarily dependent on whether the cell expressed the heterologous or homologous form of gD but rather on the properties of the virus. Marker transfer experiments revealed that the allele of gD expressed by the virus was a major determinant of sensitivity to interference. Amino acid substitutions in the most distal part of the gD ectodomain had a major effect, but substitutions solely in the cytoplasmic domain also influenced sensitivity to interference. In addition, evidence was obtained that another viral gene(s) in addition to the one encoding gD can influence sensitivity to interference. The results indicate that HSV-1 and HSV-2 gD share determinants required to mediate interference with infection by HSV of either serotype and that the pathway of HSV entry that is blocked by expression of cell-associated gD can be cleared or bypassed through subtle alterations in virion-associated proteins, particularly gD.Cells expressing gD of herpes simplex virus type 1 (HSV-1) can be resistant to infection by HSV-1 or HSV-2 (3, 11). This has been shown for several cell types, including human Hep-2 cells, mouse L cells, and baby hamster kidney (BHK) cells. This gD-mediated interference with HSV infection is at the level of viral penetration into cells, not viral binding or postpenetration steps (3,8,11).The phenomenon of gD-mediated interference is common to several of the alphaherpesviruses. Cells expressing pseudorabies virus (PRV) or bovine herpesvirus type 1 (BHV-1) gD are also resistant to infection by homologous virus (5,6,28). In addition, cross-interference among different alphaherpesviruses has been noted (5,6,12,22). For example, cells expressing BHV-1 gD are at least partially resistant to infection by BHV-1, PRV, and HSV-1 (5). Cross-interference is not always reciprocal (5,6). The patterns of cross-interference observed indicate that both homologous and heterologous forms of gD have determinants capable of blocking the entry of a single virus and that different alphaherpesviruses may have common requirements for entry that can be blocked by a single form of gD. This is despite limited conservation of primary amino acid sequence among the gD homologs (10 to 35% identity), the absence of cross-neutralizing epitopes, and differences in host range among the alphaherpesviruses.The entry of HSV, PRV, and BHV-1 into cells depends on binding of the virus to cell surface glycosaminoglycans via gC, followed by fusion of the virion envelope with a cell membrane. The available evidence indicates that at least four envelope glycoproteins, designated gB, gD, gH, and gL, are required for the fusion or penetration step. These glycoproteins are present

“…Other cell lines resistant to virus entry have been used for the isolation of escape mutants that can grow more efficiently than wild-type virus on the resistant cells. Several groups have reported the properties of viruses carrying mutations in the gene encoding gD that grow more efficiently than the wild-type virus on cells that express gD or on a cell line that expresses the HSV-1 U s 11 gene product (2,7,8,34). If the mechanism of resistance to infection shown by 95-19 cells is essentially the same as that seen in these other resistant cell types, these mutant viruses should show a similarly enhanced ability to infect 95-19 cells.…”

Section: -19 Cells Are Resistant To Virus Entry By Cell-to-cell Sprmentioning

confidence: 99%

“…Several groups have isolated lines that express gD from HSV-1 or HSV-2 and are resistant to HSV infection (6,23). These cells have been used for the selection of escape mutants of HSV-1 that can grow more efficiently than wild-type, and which map in the gD gene, suggesting that these cells fail to support an essential interaction between the cell surface and gD (2,(6)(7)(8).…”

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confidence: 99%

Characterization of a BHK(TK-) cell clone resistant to postattachment entry by herpes simplex virus types 1 and 2

Roller

Herold

1997

BHK(TK ؊ ) cells selected for resistance to polyethylene glycol-mediated fusion give rise to clones that are resistant to herpes simplex virus (HSV) infection. We have characterized one such clone, designated 95-19, and found that it is resistant to entry of HSV type 1 (HSV-1), HSV-2, and the related alphaherpesvirus pseudorabies virus (PRV). Single-step growth experiments show no detectable replication of multiple strains of HSV-1 and HSV-2 on 95-19 cells. Three lines of evidence suggest that these cells are resistant to postattachment entry. (i) Measurements of binding of radiolabeled virus show that heparin-sensitive binding of HSV-1 and HSV-2 to 95-19 cells is identical to binding to BHK(TK ؊ ) cells, suggesting that the block to replication occurs after attachment to heparan sulfate proteoglycan. (ii) 95-19 cells exposed to HSV-1 or HSV-2 at high multiplicity show no detectable immediate-early (IE) mRNA expression. (iii) Exposure of attached virus and cells to polyethylene glycol results in partial recovery of both IE gene expression and virus yield in single-step growth.The degrees of recovery of single-step yield and IE gene expression are similar, suggesting that the only block to single-step replication is at the point of virus entry and that these cells are deficient in some cellular factor required for efficient postattachment entry of free virus. 95-19 cells are also highly resistant to entry by cell-to-cell spread, suggesting that the same cellular factor participates in both types of entry.