Antiapoptotic activity of herpes simplex virus type 2: the role of US3 protein kinase gene

In order to determine the ability of herpes simplex virus type 2 (HSV-2) to suppress apoptosis, we examined the effect of HSV-2 infection on apoptosis induced in HEp-2 cells by treatment with 1 M sorbitol. Although a wild-type strain of HSV-2 induced apoptosis in a significant fraction of the infected cells, HSV-2 could suppress sorbitol-induced apoptosis in a manner similar to that of herpes simplex virus type 1 (HSV-1), indicating that HSV-2, like HSV-1, has an antiapoptosis gene. Characterization of the cells infected with a US3-deletion mutant of HSV-2 revealed the necessity of a US3 gene in the antiapoptotic activity of this virus.     

Induction and prevention of apoptosis in human HEp-2 cells by herpes simplex virus type 1

Cultured human epithelial cells infected with an ICP27 deletion strain of herpes simplex virus type 1 (HSV-1) show characteristic features of apoptotic cells including cell shrinkage, nuclear condensation, and DNA fragmentation. These cells do not show such apoptotic features when infected with a wild-type virus unless the infections are performed in the presence of a protein synthesis inhibitor. Thus, both types of virus induce apoptosis, but the ICP27-null virus is unable to prevent this process from killing the cells. In this report, we show that this ICP27-deficient virus induced apoptosis in human HEp-2 cells through a pathway which involved the activation of caspase-3 and the processing of the death substrates DNA fragmentation factor and poly(ADP-ribose) polymerase. The induction of apoptosis by wild-type HSV-1 occurred prior to 6 h postinfection (hpi), and de novo viral protein synthesis was not required to induce the process. The ability of the virus to inhibit apoptosis was shown to be effective between 3 to 6 hpi. Wild-type HSV-1 infection was also able to block the apoptosis induced in cells by the addition of cycloheximide, staurosporine, and sorbitol. While U(S)3- and ICP22-deficient viruses showed a partial prevention of apoptosis, deletion of either the U(L)13 or vhs gene products did not affect the ability of HSV-1 to prevent apoptosis in infected cells. Finally, we demonstrate that in UV-inactivated viruses, viral binding and entry were not sufficient to induce apoptosis. Taken together, these results suggest that either gene expression or another RNA metabolic event likely plays a role in the induction of apoptosis in HSV-1-infected human cells.     

Differences in inhibition of apoptosis depending on the virulence of used herpes simplex virus type 1 strains. Function of interferon alpha in apoptotic death of virus infected cells

The purpose of the present study was to determine whether there is the relation between the virulence of used HSV-1 strains and inhibition of apoptosis. HEp-2 cells were induced to apoptosis by osmotic shock after infection by HSV-1 strains. HSV-1 ts, earlier described as less virulent for mice inhibited apoptosis in smaller degree than native strain and HSV-1 tr. We suggest that this is due to the hyperproduction of IFN alpha by human cells after the stimulation by this strain. All strains of HSV-1 didn't inhibit apoptosis in the presence of IFN alpha and apoptosis was inhibited by anti IFN alpha antibodies. We confirm that IFN alpha plays an important function in controlling acute HSV-1 infection.     

Accumulation of herpes simplex virus type 1 early and leaky-late proteins correlates with apoptosis prevention in infected human HEp-2 cells

We previously reported that a recombinant ICP27-null virus stimulated, but did not prevent, apoptosis in human HEp-2 cells during infection (M. Aubert and J. A. Blaho, J. Virol. 73:2803-2813, 1999). In the present study, we used a panel of 15 recombinant ICP27 mutant viruses to determine which features of herpes simplex virus type 1 (HSV-1) replication are required for the apoptosis-inhibitory activity. Each virus was defined experimentally as either apoptotic, partially apoptotic, or nonapoptotic based on infected HEp-2 cell morphologies, percentages of infected cells with condensed chromatin, and patterns of specific cellular death factor processing. Viruses d27-1, d1-5, d1-2, M11, M15, M16, n504R, n406R, n263R, and n59R are apoptotic or partially apoptotic in HEp-2 cells and severely defective for growth in Vero cells. Viruses d2-3, d3-4, d4-5, d5-6, and d6-7 are nonapoptotic, demonstrating that ICP27 contains a large amino-terminal region, including its RGG box RNA binding domain, which is not essential for apoptosis prevention. Accumulations of viral TK, VP16, and gD but not gC, ICP22, or ICP4 proteins correlated with prevention of apoptosis during the replication of these viruses. Of the nonapoptotic viruses, d4-5 did not produce gC, indicating that accumulation of true late gene products is not necessary for the prevention process. Analyses of viral DNA synthesis in HEp-2 cells indicated that apoptosis prevention by HSV-1 requires that the infection proceeds to the stage in which viral DNA replication takes place. Infections performed in the presence of the drug phosphonoacetic acid confirmed that the process of viral DNA synthesis and the accumulation of true late (gamma(2)) proteins are not required for apoptosis prevention. Based on our results, we conclude that the accumulation of HSV-1 early (beta) and leaky-late (gamma(1)) proteins correlates with the prevention of apoptosis in infected HEp-2 cells.     

Effects of non toxic doses of acyclovir on nitric oxide and cellular death responses in herpesvirus types 1 and 2 infected hep-2 cells

Herpes simplex virus type-1 (HSV-1) and type-2 (HSV-2) are among the most "successful" pathogens and code for a variety of proteins to direct the apoptosis/necrosis responses of the cells they infect. Nitric oxide (NO) is an important intracellular signaling molecule in pathological processes. Acyclovir (ACV) is a chain terminator that targets the viral DNA polymerase as an antiviral agent. In this study, NO signals, and apoptosis/necrosis responses of HEp-2 cells were compared when infected by HSV-1 and -2 for 24 hours against non toxic doses (starting from 48.8, 24.4, 12.2, 6.1, 3 to 1.5 microg/mL) of ACV. In 48.8, 24.4 and 12.2 microg/mL of ACV, HSV-1 had an "upregulating effect" whereas HSV-2 had a "downregulating effect" on NO production, and in 6.1, 3 and 1.5 microg/mL of ACV HSV-1 had a "down-regulating effect" whereas HSV-2 had an "upregulating effect" on NO responses (HSV-1 had a "downregulating effect" on NO production whereas HSV-2 had an "upregulating effect" on NO production without any ACV). In 48.8, 24.4 and 12.2 microg/mL of ACV, HSV-1 had an "anti-apoptotic effect" whereas HSV-2 had a stimulation on "apoptotic effect", and in 6.1, 3 and 1.5 microg/mL of ACV HSV-1 had an "apoptotic effect" and HSV-2 turned to "its natural viral apoptotic effect level" (HSV-1 had an "natural viral apoptotic effect" whereas HSV-2 had a "natural viral apoptotic effect" on apoptosis response without any ACV). In 48.8, and 24.4 microg/mL of ACV, HSV-1 had significant "necrotic effect" on necrotic cellular death, "necrosis" increased in 12.2, 6.1, 3 and 1.5 microg/mL of ACV (HSV-1 had a negligible "necrotic effect" on HEp-2 cells alone), and HSV-2 had a "natural viral necrotic effect" alone; and also in all non toxic ACV concentrations. These results showed that HSV-1 and -2 had different "strategies" on apoptosis/necrosis and NO with and without non toxic ACV. These differences deserve further studies in order to explain the interactions between apoptotic/anti apoptotic, necrotic genes and NO, and ACV in HSV-1 and HSV-2 infections respectively.     

Early passage neonatal and adult keratinocytes are sensitive to apoptosis induced by infection with an ICP27-null mutant of herpes simplex virus 1

Herpes simplex virus 1 (HSV-1) is a enveloped, double stranded DNA virus that is the causative agent of various diseases including cold sores, encephalitis, and ocular keratitis. Previous research has determined that HSV-1 modulates cellular apoptotic pathways. Apoptosis is triggered in infected cells early in infection; however, later in the infection the apoptotic response is suppressed due to the expression of several viral apoptotic antagonists. This sets us a delicate balance between pro- and anti-apoptotic processes during the lytic phase of infection. Several studies have demonstrated that the apoptotic balance can be shifted during infection of certain cell types, leading to apoptosis of the infected cells (HSV-1-dependent apoptosis). For example, HEp-2 cells infected with an ICP27-null recombinant HSV-1 virus undergo HSV-1-dependent apoptosis. Differences in the sensitivity to HSV-1-dependent apoptosis have been revealed. Although many tumor cells have been found to be highly sensitive to this apoptotic response, with the exception hematological cells, all primary human cells tested prior to this study have been shown to be resistant to HSV-1-dependent apoptosis. Here, we demonstrate that early passage neonatal and adult human keratinocytes, which are usually the first cells to encounter HSV-1 in human infection and support the lytic stage of the life cycle, display membrane blebbing and ballooning, chromatin condensation, caspase activation, and cleavage of cellular caspase substrates when infected with an ICP27-null recombinant of HSV-1. Furthermore, caspase activation is needed for the efficient apoptotic response. These results suggest that apoptotic machinery may be a target for modulating HSV-disease in patients.     

Herpes simplex virus blocks apoptosis by precluding mitochondrial cytochrome c release independent of caspase activation in infected human epithelial cells

Expression of HSV-1 genes leads to the induction of apoptosis in human epithelial HEp-2 cells but the subsequent synthesis of infected cell protein prevents the process from killing the cells. Thus, viruses unable to produce appropriate prevention factors are apoptotic. We now report that the addition of either a pancaspase inhibitor or caspase-9-specific inhibitor prevented cells infected with an apoptotic HSV-1 virus from undergoing cell death. This result indicated that HSV-1-dependent apoptosis proceeds through the mitochondrial apoptotic pathway. However, the pancaspase inhibitor did not prevent the release of cytochrome c from mitochondria, implying that caspase activation is not required for this induction of cytochrome c release by HSV-1. The release of cytochrome c was first detected at 9 hpi while caspase-9, caspase-3 and PARP processing were detected at 12 hpi. Finally, Bax accumulated at mitochondria during apoptotic, but not wild type HSV-1 infection. Together, these findings indicate that HSV-1 blocks apoptosis by precluding mitochondrial cytochrome c release in a caspase-independent manner and suggest Bax as a target in infected human epithelial cells.     

Herpes simplex virus 1 blocks caspase-3-independent and caspase-dependent pathways to cell death

Earlier reports have shown that herpes simplex virus 1 (HSV-1) mutants induce programmed cell death and that wild-type HSV blocks the execution of the cell death program triggered by viral gene products, by the effectors of the immune system such as the Fas and tumor necrosis factor pathways, or by nonspecific stress agents such as either osmotic shock induced by sorbitol or thermal shock. A report from this laboratory showed that caspase inhibitors do not block DNA fragmentation induced by infection with the HSV-1 d120 mutant. To identify the events in programmed cell death induced and blocked by HSV-1, we examined cells infected with wild-type virus or the d120 mutant or cells infected and exposed to sorbitol. We report that: (i) the HSV-1 d120 mutant induced apoptosis by a caspase-3-independent pathway inasmuch as caspase 3 was not activated and DNA fragmentation was not blocked by caspase inhibitors even though the virus caused cytochrome c release and depolarization of the inner mitochondrial membrane. (ii) Cells infected with wild-type HSV-1 exhibited none of the manifestations associated with programmed cell death assayed in these studies. (iii) Uninfected cells exposed to osmotic shock succumbed to caspase-dependent apoptosis inasmuch as cytochrome c was released, the inner mitochondrial potential was lost, caspase-3 was activated, and chromosomal DNA was fragmented. (iv) Although caspase-3 was activated in cells infected with wild-type HSV-1 and exposed to sorbitol, cytochrome c outflow, depolarization of the inner mitochondrial membrane, and DNA fragmentation were blocked. We conclude that although d120 induces apoptosis by a caspase-3-independent pathway, the wild-type virus blocks apoptosis induced by this pathway and also blocks the caspase-dependent pathway induced by osmotic shock. The block in the caspase-dependent pathway may occur downstream of caspase-3 activation.     

Herpes simplex virus type-1 immediate-early gene expression and shut off of host protein synthesis are inhibited in neomycin-treated human epidermoid carcinoma 2 cells

Infection of human epidermoid carcinoma-2 (HEp-2) cells by Herpes simplex virus type 1 (HSV-1) leads to significant activation of inositol phospholipid turnover after 15 min. The effect of neomycin, an inhibitor of inositol phospholipid turnover, has been investigated for its effect on HSV-1 multiplication in HEp-2 cells. HSV-1 multiplication is inhibited by neomycin. This inhibition is not due to a block of virus adsorption or penetration. Neomycin inhibits the expression of virus immediate-early genes, as well as expression of early genes and viral DNA synthesis. In neomycin-treated cells, the usual virion-associated shut off of host protein synthesis does not occur. These results indicate that the inositol phospholipid pathway is involved in immediate-early gene expression and shut off of host protein synthesis in HEp-2 cells.     

Herpes simplex virus UL14 protein blocks apoptosis

We report that an HSV-2 UL14 protein expressing cell line (14/HEp-2) was more resistant to apoptosis induced by osmotic shock and certain drugs than its parental cell line. Furthermore, HSV-1 UL14 protein deletion virus (UL14D) showed weaker inhibition of apoptosis compared to the rescued virus UL14R. The protein's anti-apoptotic function may derive from its heat shock protein-like properties.     

Similarities and differences in the Fc-binding glycoprotein (gE) of herpes simplex virus types 1 and 2 and tentative mapping of the viral gene for this glycoprotein.

We performed affinity chromatography and immunoprecipitation experiments to determine whether cells infected with herpes simplex virus type 2 (HSV-2) expressed a glycoprotein that was functionally and antigenically related to the HSV-1 Fc-binding glycoprotein designated gE. We found that a protein from extracts of HSV-2-infected HEp-2 cells bound specifically to an Fc affinity column and that the electrophoretic mobility of this protein in sodium dodecyl sulfate-acrylamide gels was slightly less than the mobility of HSV-1 gE. Immunoprecipitation experiments performed with an antiserum prepared against HSV-1 gE revealed that (i) extracts from HSV-2-infected cells contained a glycoprotein that was antigenically related to HSV-1 gE; (ii) the electrophoretic mobility of the HSV-2 gE was indistinguishable from the mobility of the HSV-2 Fc-binding protein; (iii) the antiserum reacted with both newly synthesized transient forms and stable fully processed forms of both HSV-1 gE and HSV-2 gE; and (iv) the transient and stable forms of HSV-2 gE all had lower electrophoretic mobilities than their HSV-1 counterparts. Electrophoretic analyses of gE precipitated from extracts of HEp-2 cells infected with two sets of HSV-1 x HSV-2 intertypic recombinant viruses suggested that the gene for gE is located at the right end of the HSV genome (0.85 to 0.97 map units) in the unique portion of the S component.     

Characterization of apoptosis induced by sorbitol: a unique system for the detection of antiapoptotic activities of viruses

The treatment of HEp-2 cells with sorbitol induced massive apoptosis rapidly. This method for inducing apoptosis is very useful to detect antiapoptotic activity of viruses as well as viral genes. Commitment to death occurred immediately upon incubation with sorbitol, even in the presence of pancaspase inhibitor, Z-VAD-FMK. Apoptosis is also induced by other polyhydric alcohols with more than four hydroxyl groups, but not induced by glycerol or ethylene glycol. Sorbitol treatment on ice did not induce apoptosis either. These results suggest that this induction of apoptosis does not result simply from high osmotic pressure but probably by the interaction of solutes through their physical nature (such as hydrophobicity) with the plasma membrane of the cells.     

In Vitro Selection of Variants of Herpes Simplex Virus Type 1 Which Differ in Cytopathic Changes

To analyze the mechanisms for in vitro emergence of the syncytial variants of herpes simplex virus type 1 (HSV-1), several cell lines were infected with a mixture of equal amounts of two HSV-1 variants, one syncytial and the other non-syncytial, and changes in their relative abundance were monitored during passage. With a combination of two variants of the Miyama strain of HSV-1, the syncytial variant became dominant during passage in Vero, RK-13 and FL cells. On the other hand, the ratios of the two variants remained around 1:1 during the passage in HEp-2, MGC and HEL cells. In another set of variants of the SKO strain of HSV-1, the outcomes were different from those of the Miyama strain in the FL, MGC and HEp-2 cells. The ratios of the two variants remained around 1:1 during passage in FL cells, while the non-syncytial variant became dominant during passage in MGC and HEp-2 cells. In addition, we examined the effects of a complement and interferon-β (IFN-β) on the outcome of the selection. As a result, the complement slowed the selection of a syncytial variant, whereas IFN-β facilitated it.     

Glycoprotein gE of herpes simplex virus type 1: effects of anti-gE on virion infectivity and on virus-induced fc-binding receptors.

An Fc-binding glycoprotein, designated gE, was detected previously in cells infected with herpes simplex virus type 1 (HSV-1) and in virion preparations isolated from infected cells. For the studies reported here, we purified gE from HSV-1 strain HFEM(syn) by affinity chromatography and preparative electrophoresis and then immunized a rabbit to produce an antiserum to glycoprotein gE. We found that this antiserum selectively precipitated gE and its precursors from detergent-solubilized extracts of HSV-1 strain HFEM(syn)-infected HEp-2 cells, from extracts of other cell lines infected with the same virus, and from extracts of HEp-2 cells infected with several other HSV-1 strains. The antiserum did not precipitate any proteins from uninfected cells. The several forms of gE detected by immunoprecipitation accumulated in variable quantities in different cells infected with the different virus strains and also varied slightly with respect to electrophoretic mobility, suggesting some differences in the gE's from different HSV-1 strains and some effects of the host cell on the nature and extent of post-translational processing. One of the electrophoretic forms of gE previously detected in purified preparations of virions could be precipitated by anti-gE from extracts of purified HSV-1 strain HFEM(syn) virions. Moreover, anti-gE neutralized HSV-1 infectivity, but only in the presence of complement. Finally, F(ab')2 fragments of the anti-gE immunoglobulin partially inhibited the binding of 125I-labeled immunoglobulin G to the Fc receptors on HSV-1-infected cells.     

Application of antibody to synthetic peptides for characterization of the intact and truncated alpha 22 protein specified by herpes simplex virus 1 and the R325 alpha 22- deletion mutant.

The alpha 22 protein is one of five proteins synthesized immediately after infection of permissive cells with herpes simplex virus 1 and 2 (HSV-1 and HSV-2). On the basis of the reported nucleotide sequence of the HSV-1 gene, we synthesized two peptides containing the predicted amino acids 12 through 23 (12 residues) and 21 through 36 (16 residues) in two hydrophilic domains near the N terminus of the protein. Rabbit antisera made against these peptides were then used to characterize the alpha 22 protein made by wild-type HSV-1(F) strain and by an HSV-1 mutant, R325, carrying a 500-base-pair deletion within the coding domain of the gene. The results were as follows. (i) Both antisera reacted with HSV-1(F) alpha 22 protein in lysates electrophoretically separated in denaturing polyacrylamide gels and electrically transferred to a nitrocellulose sheet; neither antiserum reacted with the corresponding HSV-2 protein. The protein accumulated at 34 and 39 degrees C in the nucleus of infected permissive HEp-2 and baby hamster kidney (BHK) cells. The protein formed at least five spots differing in charge, mobility, and extent of phosphorylation on two-dimensional electrophoretic separation. (ii) The antisera reacted with a truncated nuclear protein (33,700 apparent molecular weight) in permissive HEp-2 and restrictive BHK cells infected with R325 and incubated at 39 degrees C but not at 34 degrees C. The truncated protein represents, therefore, the product of the undeleted 5' domain of the alpha 22 gene in R325. (iii) The presence of identical as well as slower migrating, reactive proteins in infected BHK cell lysates indicated that wild-type and truncated alpha 22 proteins are processed differently in BHK and HEp-2 cells.