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

We characterized the glycoprotein K (gK)-null herpes simplex virus type 1 [HSV-1] (KOS) delta gK and compared it to the gK-null virus HSV-1 F-gKbeta (L. Hutchinson et al., J. Virol. 69:5401-5413, 1995). delta gK and F-gKbeta mutant viruses produced small plaques on Vero cell monolayers at 48 h postinfection. F-gKbeta caused extensive fusion of 143TK cells that was sensitive to melittin, a specific inhibitor of gK-induced cell fusion, while delta gK virus did not fuse 143TK cells. A recombinant plasmid containing the truncated gK gene specified by F-gKbeta failed to rescue the ICP27-null virus KOS (d27-1), while a plasmid with the delta gK deletion rescued the d27-1 virus efficiently. delta gK virus yield was approximately 100,000-fold lower in stationary cells than in actively replicating Vero cells. The plaquing efficiencies of delta gK and F-gKbeta virus stocks on VK302 cells were similar, while the plaquing efficiency of F-gKbeta virus stocks on Vero cells was reduced nearly 10,000-fold in comparison to that of delta gK virus. Mutant delta gK and F-gKbeta infectious virions accumulated within Vero and HEp-2 cells but failed to translocate to extracellular spaces. delta gK capsids accumulated in the nuclei of Vero but not HEp-2 cells. Enveloped delta 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 delta 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 delta gK virus. Comparison of delta gK and F-gKbeta viruses suggests that the inefficient viral replication and plaquing efficiency of F-gKbeta virus in Vero cells and its syncytial phenotype in 143TK- cells are most likely due to expression of a truncated gK.

[1]  P. Desai,et al.  Excretion of non-infectious virus particles lacking glycoprotein H by a temperature-sensitive mutant of herpes simplex virus type 1: evidence that gH is essential for virion infectivity. , 1988, The Journal of general virology.

[2]  S. Person,et al.  Nucleotide sequence specifying the glycoprotein gene, gB, of herpes simplex virus type 1. , 1984, Virology.

[3]  K. Pogue-Geile,et al.  Fine mapping of mutations in the fusion-inducing MP strain of herpes simplex virus type 1. , 1984, Virology.

[4]  H. M. Rose,et al.  ELECTRON MICROSCOPIC OBSERVATIONS ON THE DEVELOPMENT OF HERPES SIMPLEX VIRUS , 1959, The Journal of experimental medicine.

[5]  K. Kousoulas,et al.  Truncation of the carboxy-terminal 28 amino acids of glycoprotein B specified by herpes simplex virus type 1 mutant amb1511-7 causes extensive cell fusion , 1993, Journal of virology.

[6]  L. Moss,et al.  Herpesvirus Envelopment , 1968, Journal of virology.

[7]  H. M. Rose,et al.  Electron Microscopy of Herpes Simplex Virus , 1968, Journal of virology.

[8]  S. Brown,et al.  ICP34.5 influences herpes simplex virus type 1 maturation and egress from infected cells in vitro. , 1994, The Journal of general virology.

[9]  A. L. Goldin,et al.  Cloning of herpes simplex virus type 1 sequences representing the whole genome , 1981, Journal of virology.

[10]  V. Chouljenko,et al.  Efficient long-PCR site-specific mutagenesis of a high GC template. , 1996, BioTechniques.

[11]  B. Roizman,et al.  Redistribution of microtubules and Golgi apparatus in herpes simplex virus-infected cells and their role in viral exocytosis , 1995, Journal of virology.

[12]  R. Ramaswamy,et al.  Syncytial mutations in the herpes simplex virus type 1 gK (UL53) gene occur in two distinct domains , 1994, Journal of virology.

[13]  A. Davison,et al.  Thymidine kinase deletion mutants of herpes simplex virus type 1. , 1982, The Journal of general virology.

[14]  L. Enquist,et al.  Effect of brefeldin A on alphaherpesvirus membrane protein glycosylation and virus egress , 1991, Journal of virology.

[15]  T. Compton,et al.  Virus-specific glycoproteins associated with the nuclear fraction of herpes simplex virus type 1-infected cells , 1984, Journal of virology.

[16]  P. Pellett,et al.  Mutations affecting conformation or sequence of neutralizing epitopes identified by reactivity of viable plaques segregate from syn and ts domains of HSV-1(F) gB gene. , 1984, Virology.

[17]  S. Person,et al.  Nucleotide sequence of a region of the herpes simplex virus type 1 gB glycoprotein gene: mutations affecting rate of virus entry and cell fusion. , 1984, Virology.

[18]  B. Banfield,et al.  Herpes simplex virus particles are unable to traverse the secretory pathway in the mouse L-cell mutant gro29 , 1990, Journal of virology.

[19]  D. Knipe,et al.  Genetic evidence for two distinct transactivation functions of the herpes simplex virus alpha protein ICP27 , 1990, Journal of virology.

[20]  P. Spear,et al.  Viral and cellular factors that influence cell fusion induced by herpes simplex virus. , 1980, Virology.

[21]  S. Person,et al.  The isolation and characterization of mutants of herpes simplex virus type 1 that induce cell fusion. , 1982, The Journal of general virology.

[22]  H. Browne,et al.  An endoplasmic reticulum-retained herpes simplex virus glycoprotein H is absent from secreted virions: evidence for reenvelopment during egress , 1996, Journal of virology.

[23]  S. Person,et al.  Alterations of Neutral Glycolipids in Cells Infected with Syncytium-Producing Mutants of Herpes Simplex Virus Type 1 , 1977, Journal of virology.

[24]  L. Hutchinson,et al.  Herpes simplex virus glycoprotein K is known to influence fusion of infected cells, yet is not on the cell surface , 1995, Journal of virology.

[25]  D C Johnson,et al.  Herpes simplex virus glycoprotein K promotes egress of virus particles , 1995, Journal of virology.

[26]  C. Stackpole Herpes-Type Virus of the Frog Renal Adenocarcinoma , 1969, Journal of virology.

[27]  F. Homa,et al.  Resolution of genotypic and phenotypic properties of herpes simplex virus type 1 temperature-sensitive mutant (KOS) tsZ47: evidence for allelic complementation in the UL28 gene. , 1993, Virology.

[28]  E. Avitabile,et al.  Individual herpes simplex virus 1 glycoproteins display characteristic rates of maturation from precursor to mature form both in infected cells and in cells that constitutively express the glycoproteins. , 1988, Virus research.

[29]  S. Weller,et al.  An ICP6::lacZ insertional mutagen is used to demonstrate that the UL52 gene of herpes simplex virus type 1 is required for virus growth and DNA synthesis , 1988, Journal of virology.

[30]  B. Roizman,et al.  Molecular Genetics of Herpes Simplex Virus II. Mapping of the Major Viral Glycoproteins and of the Genetic Loci Specifying the Social Behavior of Infected Cells , 1979, Journal of virology.

[31]  S. Person,et al.  The effect of ammonium chloride and tunicamycin on the glycoprotein content and infectivity of herpes simplex virus type 1. , 1983, Virology.

[32]  B. Roizman,et al.  Glycoprotein D of herpes simplex virus encodes a domain which precludes penetration of cells expressing the glycoprotein by superinfecting herpes simplex virus , 1990, Journal of virology.

[33]  R. Manservigi,et al.  Cell fusion induced by herpes simplex virus is promoted and suppressed by different viral glycoproteins. , 1977, Proceedings of the National Academy of Sciences of the United States of America.

[34]  K. Pogue-Geile,et al.  The single base pair substitution responsible for the Syn phenotype of herpes simplex virus type 1, strain MP. , 1987, Virology.

[35]  D. McGeoch,et al.  Investigation of herpes simplex virus type 1 genes encoding multiply inserted membrane proteins. , 1991, The Journal of general virology.

[36]  S. Nii Electron microscopic study on the development of herpesviruses. , 1992, Journal of electron microscopy.

[37]  B. Roizman,et al.  Origin of unenveloped capsids in the cytoplasm of cells infected with herpes simplex virus 1 , 1991, Journal of virology.

[38]  E. Southern Detection of specific sequences among DNA fragments separated by gel electrophoresis. , 1975, Journal of molecular biology.

[39]  B. Roizman,et al.  The UL20 gene of herpes simplex virus 1 encodes a function necessary for viral egress , 1991, Journal of virology.

[40]  S. Person,et al.  Nucleotide sequence of a herpes simplex virus type 1 gene that causes cell fusion. , 1985, Virology.

[41]  H. Okayama,et al.  High-efficiency transformation of mammalian cells by plasmid DNA. , 1987, Molecular and cellular biology.

[42]  K. Kousoulas,et al.  Role of the Na+,K+ pump in herpes simplex type 1-induced cell fusion: melittin causes specific reversion of syncytial mutants with the syn1 mutation to Syn+ (wild-type) phenotype. , 1993, Virology.

[43]  V. Bond,et al.  Fine structure physical map locations of alterations that affect cell fusion in herpes simplex virus type 1. , 1984, Virology.

[44]  H. Toolan,et al.  Culture characteristics of four permanent lines of human cancer cells. , 1955, Cancer research.

[45]  A. Baghian,et al.  Antibody response to epitopes of chlamydial major outer membrane proteins on infectious elementary bodies and of the reduced polyacrylamide gel electrophoresis-separated form , 1990, Infection and immunity.

[46]  H. M. Rose,et al.  Electron Microscopy of Herpes Simplex Virus , 1968, Journal of virology.

[47]  B. Roizman,et al.  Localization and putative function of the UL20 membrane protein in cells infected with herpes simplex virus 1 , 1994, Journal of virology.

[48]  P. Pellett,et al.  Anatomy of the herpes simplex virus 1 strain F glycoprotein B gene: primary sequence and predicted protein structure of the wild type and of monoclonal antibody-resistant mutants , 1985, Journal of virology.

[49]  S. Person,et al.  Genetic studies of cell fusion induced by herpes simplex virus type 1 , 1980, Journal of virology.

[50]  P. Spear,et al.  Monensin inhibits the processing of herpes simplex virus glycoproteins, their transport to the cell surface, and the egress of virions from infected cells , 1982, Journal of virology.

[51]  F. Graham,et al.  Identification and characterization of a novel herpes simplex virus glycoprotein, gK, involved in cell fusion , 1992, Journal of virology.

[52]  B. Roizman,et al.  Concerning the egress of herpes simplex virus from infected cells: electron and light microscope observations. , 1969, Virology.

[53]  D. Coen,et al.  A conserved open reading frame that overlaps the herpes simplex virus thymidine kinase gene is important for viral growth in cell culture , 1989, Journal of virology.