Direct lymphocytotoxicity against herpes simplex virus infected cells.

This study was undertaken to determine if direct cytotoxicity (DC) against herpes simplex virus infected cells, perhaps mediated by T cells, could be demonstrated in individuals subject to recurrent herpes labialis. The mononuclear cells from 7 out of 17 individuals with recurrent herpes expressed DC whereas no DC was ever exhibited by 7 individuals without a previous history of herpes infections. Several approaches were used to show that the cytotoxicity being detected was predominately of the direct type rather than antibody-dependent cell cytotoxicity (ADCC). Since the effector cells of the DC were sensitive to trypsin treatment and behaved as do natural killer (NK) cells upon cell fractionation, the results were taken to imply that the DC was attributable to a NK-effector cell type rather than a classical T lymphocyte.     

Acid pH-induced fusion of cells by herpes simplex virus glycoproteins gB an gD

Enveloped animal viruses enter host cells either by direct fusion at neutral pH or by endocytosis. Herpes simplex virus (HSV) is believed to fuse with the plasma membrane of cells at neutral pH, and the glycoproteins gB and gD have been implicated in virus entry and cell fusion. Using cloned gB or gD genes, we show that cells expressing HSV-1 glycoproteins gB or gD can undergo fusion to form polykaryons by exposure only to acidic pH. The low pH-induced cell fusion was blocked in the presence of monoclonal antibodies specific to the glycoproteins. Infection of cells expressing gB or gD glycoproteins with HSV-1 inhibited the low pH-induced cell fusion. The results suggest that although the glycoproteins gB and gD possess fusogenic activity at acidic pH, other HSV proteins may regulate it such that in the virus-infected cell, this fusion activity is blocked.     

Search for multienzyme complexes of DNA precursor pathways in uninfected mammalian cells and in cells infected with herpes simplex virus type I

Confirmatory evidence for the existence of a multienzyme complex of DNA precursor pathways in mammalian cells was obtained. Using neutral sucrose gradient centrifugation of cell lysates we found that at least five enzymes involved in DNA precursor metabolism in uninfected. S-phase BHK-cell fibroblasts cosediment at a common rate, indicative of a multienzyme complex. The enzymes include DNA polymerase thymidine kinase, ribonucleotide reductase, dihydrofolate reductase, and NDP-kinase. This complex was partially, but not completely, disrupted when lysates from GO-phase cells were centrifuged. Using lysates from cells infected with herpes simplex virus (HSV) type I some of the virus-induced ribonucleotide reductase and a minor proportion of the HSV-thymidine kinase cosedimented rapidly. The virus-induced DNA polymerase sedimented independently near the middle of the gradient, in contrast to the behaviour of the host polymerase. The enzyme associations observed were disrupted by NaCl or by inclusion of ethylenediamine tetraacetic acid during the cell lysis procedure, instead of the usual EGTA. These results indicate the importance of ionic forces in maintaining the enzyme complexes. The bulk of the DNA and the RNA present in the lysates did not sediment at the same rate as the complexes, showing that the enzymes were not simply adhering nonspecifically to these polyanions. Newly synthesised radiolabeled DNA (15 min pulse with [3H]thymidine) was not preferentially associated with the enzymes, but some functional DNA was evident in the enzyme complex fraction from the uninfected S-phase cells. DNA polymerase activity in this fraction did not require, nor was it stimulated by, exogenous "activated" DNA. Added DNA primer-template was required, however, for maximal activity of the polymerase in gradient fractions derived from GO-phase cells and from HSV-infected cells. No evidence for channeling of ribonucleotide precursors into DNA of permeabilized cells (uninfected or HSV-infected) was detected. Most rCDP was incorporated into RNA. In the uninfected, S-phase cells about 10 pmol/10(6) cells/90 min of rCDP residues was incorporated into DNA compared with 120 pmol/10(6) cells/90 min when radiolabeled dCTP was used. Nonradioactive dCTP present in equimolar concentration in the incubation with labeled rCDP did not, however, diminish the incorporation of label from the ribonucleotide. In permeabilized HSV-infected cells incorporation of radiolabel from rCDP into DNA was barely detectable.     

Analysis of herpes simplex virus nucleoprotein complexes extracted from infected cells.

HEp-2 cells were infected with herpes simplex virus type 1 and labeled with [3H]thymidine and 14C-amino acids. Infected cells or nuclei prepared from them were extracted with Triton X-100 and NaCl, utilizing a method recently described, and the low-speed supernatant (extract) was partially purified by sedimentation on sucrose gradients. A nucleoprotein complex which sedimented as a wide peak around 200S was identified. The nucleoprotein complex contained viral DNA, which banded at the expected density in CsCl isopycnic gradients and was intact after measurements taken on electron microscopic photographic enlargements. The autoradiographic pattern of 14C-labeled proteins after electrophoresis showed that only a few of the virus-specific polypeptides were present in the nucleoprotein complexes, in particular, VP5, VP12, VP15.2, VP19, and VP24. Cellular histones were absent. The extracts and the nucleoprotein complexes were centrifuged to equilibrium in metrizamide density gradients without prefixation. Electron microscopic direct visualization of the nucleoprotein complexes after sucrose or metrizamide purification revealed that the proteins were preferentially associated with one end of the DNA molecule and formed large irregular terminal thickenings or capsid-like transparent shells enclosing polyglobular cores. No nucleosomes were observed on herpes simplex virus nucleoprotein complexes. The same type of complex was detected after phosphonoacetic acid addition, and grossly altered nucleocapsids were formed.     

Interaction of concanavalin A with herpes simplex virus infected cells

Incubation of herpes simplex virus (HSV) infected cells with concanavalin A (Con A) interferes with binding of the Fc portion of antibody. In addition, the lectin inhibits complement mediated cytolysis, probably by interference with antibody binding. These results suggest that binding sites of both Fc and HSV antibody contain residues which attract Con A.     

Replication of herpes simplex virus type I DNA in permeabilized infected cells.

Herpes simplex type 1 (HSV)-infected Vero cells can be permeabilized by a combination of hypotonic shock and a mild emulsifier, gum arabic. Permeabilized cells will incorporate triphosphate precursors into viral and host DNA in vitro in ratios similar to those seen in vivo. This reaction is ATP-dependent and is shown to be replicative by the single strand density shift of DNA synthesized in the presence of BrdUTP. The product is heterogeneous in size, and contains a significant proportion of rapidly sedimenting forms and of unit size (55S) viral DNA. The presence of polyamines and EGTA (a specific chelator of Ca2+ ions) in the labeling medium is shown to be necessary to maintain the integrity of the replicating DNA. The average size of newly synthesized single strands, however, is smaller than seen in vivo. The reaction is sensitive to phosphonoacetic acid added at the time of labeling, at concentrations which inhibit in vivo synthesis only after one hour of pre-exposure. These properties make permeabilized cell monolayers an attractive system for the study of HSV DNA replication.     

The physical state of herpes simplex virus DNA in infected human cells.

Treatment of herpes simplex virus type 1 (HSV-1)-infected human embryo lung (HEL) cells with phosphonoacetic acid (PAA) resulted in complete inhibition of HSV DNA replication. DNA was extracted from PAA-treated HEL cells infected with HSV-1 and centrifuged in a neutral CsCl density gradient. The HSV DNA sequences in the nuclei of PAA treated cells at 24 hr post infection banded at the same density as free HSV DNA (1.725 g/cm3), but a significant amount of viral DNA sequences were detected in the regions of cell DNA (1.700 g/cm3) as well as in the intermediate fractions as determined by hybridization with 3H HSV complementary RNA. The viral DNA sequences of lower deisntiy did not change in density by recentrifugation in a CsCl density gradient, but did change to the density of free viral DNA after treatment with EcoR1 restriction endonuclease. When the DNA from the nuclei of PAA treated cells was analyzed in an alkaline glycerol gradient, more than 95% of the viral DNA sequences were found in the free viral DNA fractions. Since the viral and cellular hybrid DNA represented approximately 33% of the total viral DNA sequences, it is concluded that some of the HSV DNA sequences in PAA treated, infected cells are associated with cell DNA by alkali-labile bonds.     

Characteristics of chromatin preparations from herpes simplex virus infected cells

Chromatin isolated from herpes simplex virus type 1-infected baby hamster kidney cells contains a number of tightly associated virus-induced polypeptides. A subset of these proteins bind to immobilized DNA in vitro (Vmw 175, 155, 130, 63, 43, 38/39). Virus-induced polypeptides extractable with acid from infected cell chromatin include Vmw 155, the major capsid protein of herpes simplex virus type 1 virions, and Vmw 63 and 38/39 which are heterogeneous with respect to charge and are phosphorylated. These chromatin preparations, in the presence of deoxynucleoside triphosphates and MgCl2 were capable of synthesizing viral and cell DNA in a reaction which was stimulated by the addition of ATP, riboNTPs and potassium acetate. In vitro synthesized viral DNA co-sedimented with prelabelled parental DNA but the single-stranded product was smaller than parental DNA. Density labelling indicated that extensive synthesis was taking place and all BamHI fragments of viral DNA were represented by the DNA synthesized in vitro.     

The herpes simplex virus UL37 protein is phosphorylated in infected cells.

The herpes simplex virus type 1 (HSV-1) UL37 open reading frame encodes a 120-kDa late (gamma 1), nonstructural protein in infected cells. Recent studies in our laboratory have demonstrated that the UL37 protein interacts in the cytoplasm of infected cells with ICP8, the major HSV-1 DNA-binding protein. As a result of this interaction, the UL37 protein is transported to the nucleus and can be coeluted with ICP8 from single-stranded DNA columns. Pulse-labeling and pulse-chase studies of HSV-1-infected cells with [35S]methionine and 32Pi demonstrated that UL37 was a phosphoprotein which did not have a detectable rate of turnover. The protein was phosphorylated soon after translation and remained phosphorylated throughout the viral replicative cycle. UL37 protein expressed from a vaccinia virus recombinant was also phosphorylated during infection, suggesting that the UL37 protein was phosphorylated by a cellular kinase and that interaction with the ICP8 protein was not a prerequisite for UL37 phosphorylation.     

Evidence for translational regulation of herpes simplex virus type 1 gD expression.

We compared the rates of synthesis of herpes simplex virus type 1 glycoproteins C and D and quantitated the accumulation of translatable mRNA for each glycoprotein at various times after infection. The rate of synthesis of gD increased sharply early in the infection, peaked by 4 to 6 h after infection, and declined late in the infection. In contrast, the rate of synthesis of gC increased steadily until at least 15 h after infection. The levels of mRNA for both of these glycoproteins, as detected by hybridization and by translation in vitro, continued to increase until at least 15 or 16 h after infection. Synthesis of both gC and gD and their respective mRNAs was found to be sensitive to inhibition of viral DNA replication with phosphonoacetic acid. The finding that reduced amounts of gD were synthesized late in the replicative cycle, whereas gD mRNA continued to accumulate in the cytoplasm, argues that the synthesis of gD is regulated, in part, at the level of translation.     

Proteins associated with mRNA in cells infected with herpes simplex virus

The structure of messenger ribonucleoprotein (mRNP) complexes in herpes simplex virus type 1 (HSV-1) infected cells was analyzed by examining the proteins that could be crosslinked to polyadenylated mRNAs by irradiation of intact cells with ultraviolet light. The profiles of crosslinked proteins were qualitatively similar for mRNPs from mock infected and infected cells. However, infection with wild type HSV-1 caused a decrease in the abundance of a major 52 kda protein and an increase in a 49 kda protein. These changes were observed at early times after infection. They occurred following infection with wild type HSV-1 under conditions that blocked viral gene expression, but not following infection with the virion host shutoff mutant vhs 1.     

Polyphosphoinositide metabolism in baby-hamster kidney cells infected with herpes simplex virus type 1.

The incorporation of [32P]Pi and [3H]inositol into the inositol lipids of baby-hamster kidney cells was studied in herpes-simplex-virus-type-1(HSV-1)-infected and mock-infected cells. The infection was conducted during incorporation of, as well as after prelabelling with, the precursors. These methods were used in order to study both synthesis de novo of, and steady-state changes in, the phosphoinositides. Both with infection during labelling, and after prelabelling, we found increased [32P]- and [3H]-phosphatidylinositol 4,5-bisphosphate (PIP2) and decreased [32P]- and [3H]-phosphatidylinositol 4-monophosphate in infected as compared with mock-infected cells, whereas no effect was observed on phosphatidylinositol. This altered inositol-lipid metabolism was (at least in the case of PIP2) not present until 3-6 h after infection and remained stable, or increased slightly, throughout the infection period. Polyphosphoinositide metabolism constitutes an important step in signal processing in many forms of cellular stimulation, and the results obtained suggest that HSV-1 infection may induce such events in our cell system.