Host-cell reactivation in mammalian cells. I. Survival of ultra-violet-irradiated herpes virus in different cell-lines

Molecular aspects of herpes simplex virus I latency, reactivation, and recurrence

The application of molecular biology in the study of the pathogenesis of herpes simplex virus type 1 (HSV-1) has led to significant advances in our understanding of mechanisms that regulate virus behavior in sensory neurons and epithelial tissue. Such study has provided insight into the relationship of host and viral factors that regulate latency, reactivation, and recurrent disease. This review attempts to distill decades of information involving human, animal, and cell culture studies of HSV-1 with the goal of correlating molecular events with the clinical and laboratory behavior of the virus during latency, reactivation, and recurrent disease. The purpose of such an attempt is to acquaint the clinician/scientist with the current thinking in the field, and to provide key references upon which current opinions rest.

Mechanism of copper-mediated inactivation of herpes simplex virus

The inactivation of herpes simplex virus (HSV) by copper was enhanced by the following reducing agents at the indicated relative level: ascorbic acid >> hydrogen peroxide > cysteine. Treatment of HSV-infected cells with combinations of Cu(II) and ascorbate completely inhibited virus plaque formation to below 0.006% of the infectious virus input, while it maintained 30% viability for the host mammalian cells. The logarithm of the surviving fraction of HSV mediated by 1 mg of Cu(II) per liter and 100 mg of reducing agent per liter followed a linear relationship with the reaction time, in which the kinetic rate constant for each reducing agent was -0.87 min(-1) (r = 0.93) for ascorbate, -0.10 min(-1) (r = 0.97) for hydrogen peroxide, and -0.04 min(-1) (r = 0.97) for cysteine. The protective effects of metal chelators and catalase, the lack of effect of superoxide dismutase, and the partial protection conferred by free-radical scavengers suggest that the mechanism of copper-mediated HSV inactivation is similar to that previously reported for copper-mediated DNA damage. The sensitivity exhibited by HSV to Cu(II) and reducing agents, particularly ascorbate, might be useful in the development of therapeutic antiviral agents.

Herpes virus infection and repair in cells pretreated with gilvocarcin V or merocyanine 540 and radiation

Pretreatment of mammalian cells with certain genotoxic agents decreases the ability of the cell monolayers to support virus plaque formation but enhances repair of UV-irradiated virus. This study was made to determine whether these phenomena extend to pretreatments with light and photosensitizers, including one dye that primarily affects cell membranes. Confluent CV-1 monkey kidney fibroblast monolayers were pretreated with either gilvocarcin V (GV) or merocyanine 540 (MC540) and light of appropriate wavelengths and infected with control or UV-irradiated herpes simplex virus (HSV). GV phototreatment is known to affect cells at the DNA level, and MC540 at the membrane level. UV radiation served as a positive control pretreatment. Phototoxic concentrations of GV and MC540 were determined via the capacity of pretreated cell monolayers to support plaque formation by unirradiated HSV. Parallel monolayer pretreatment and subsequent infection by UV-irradiated HSV demonstrated that both types of phototreatments enhanced virus survival, but the dose responses and time courses were different. The DNA-damaging GV phototreatment mimicked the effect of UV-irradiating the cells and produced delayed enhanced repair of UV-irradiated virus. However, the MC540-phototreatment produced enhancement of virus survival with a bimodal dose response pattern for immediate infection, suggesting a different route for affecting repair of damaged virus.

Virus inactivation by copper or iron ions alone and in the presence of peroxide

Cupric and ferric ions were able to inactivate five enveloped or nonenveloped, single- or double-stranded DNA or RNA viruses. The virucidal effect of these metals was enhanced by the addition of peroxide, particularly for copper(II). Under the conditions of our test, mixtures of copper(II) ions and peroxide were more efficient than glutaraldehyde in inactivating phi X174, T7, phi 6, Junin, and herpes simplex viruses. The substances described here should be able to inactivate most, if not all, viruses that have been found contaminating medical devices.

Antiviral activity of gilvocarcin V plus UVA radiation

Gilvocarcin V (GV), a coumarin, is a nucleic acid photosensitizer that is phototoxic to bacteria and mammalian cells at picomolar levels in the presence of near-UV radiation (UVA). We evaluated the effectiveness of GV plus UVA for inactivation of several viruses, including herpes simplex virus, type 1 (HSV) and the bacterial viruses phi X174, T7, PRD1 and phi 6. Some inactivation of the bacterial viruses was observed with UVA radiation alone (4-50% survival at 26 kJ/m2). Additional photosensitized inactivation was observed only with T7 and phi 6 at 2.0 microM GV. On the other hand, HSV was photoinactivated with concentrations of GV three orders of magnitude lower (1.0 nM). Similar to the case with UV (254 nm) inactivation, the GV-UVA survival curve for HSV indicated multicomponent inactivation kinetics, which could not be explained by photobleaching of GV. The wide range of photosensitivities of these viruses to GV cannot be adequately explained by models based only on viral nucleic acid content or presence of lipid envelopes.

UV-enhanced replication of herpes simplex virus in DNA-repair competent and deficient fibroblasts

Replication of herpes simplex virus type 1 was enhanced in fibroblast cultures when cells were ultraviolet irradiated 12 to 48 hours before infection. Maximum enhancement (340% increase) occurred at exposures of 9.6 J/m2 in DNA-repair competent fibroblasts. Repair deficient xeroderma pigmentosum cells responded to lower ultraviolet exposures (1.6 to 5.6 J/m2) with lower levels of enhancement (37% to 140%). Ultraviolet irradiation of host cells before infection increased viral DNA synthesis, but did not alter the ability of the cell to adsorb virus. Prostaglandins were not shown to contribute to the process. These results suggest that ultraviolet-enhanced replication of herpes simplex virus may be associated with DNA-repair activities, and that ultraviolet-enhanced herpes simplex virus replication should be further examined for its contribution to herpes simplex virus recurrence in vivo.

Inactivation and mutagenesis of herpes virus by photodynamic treatment with therapeutic dyes

Dyes which photosensitize membranes may be clinically useful for photodynamic treatment (PDT) of Herpes simplex virus (HSV) infections. It is important to determine whether the enveloped HSV can be inactivated via membrane damage without affecting the genetic material. Selection of appropriate PDT conditions, including the choice of dye, could minimize viral mutagenesis. We determined the mutagenesis caused by PDT employing three membrane-photosensitizing dyes of potential use in cancer photochemotherapy (Photofrin II, polyhematoporphyrin esters, zinc phthalocyanine tetrasulfonates) and a DNA-photosensitizing dye (proflavine sulfate). The effects were compared to those caused by exposure of HSV to ultraviolet radiation (UV). The procedure consisted of incubating HSV with microgram/ml (microM) concentrations of the dye, irradiating the samples with broad spectrum visible/near-UV radiation (Daylight fluorescent lamps) and assaying the survival of the treated HSV. Zinc phthalocyanine was the most potent dye per absorbed photon for inactivating HSV. In parallel with determination of survival, progeny of the surviving virus were grown for determination of mutagenesis. The progeny virus was harvested and subsequently assayed in the presence and absence of 40 micrograms/ml iododeoxycytidine (ICrd) to determine the frequency of mutation to ICrd resistance. Mutation frequencies were determined for progeny from the 1-4% survival level. For PDT with each membrane-photosensitizing dye, only zinc phthalocyanine increased the mutation frequency over the untreated control. This increase was less than 2-fold. Proflavine increased the mutation frequency 2-3 fold over the untreated control. Ultraviolet produced a 15-20 fold increase over the untreated control.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of incorporation of 5-iodo-2'-deoxyuridine into HSV-1 DNA on virion sensitivity to ultraviolet light

First generation progeny herpes simplex type 1 (HSV-1) virions grown in the presence of 5-iodo-2'-deoxyuridine (IdUrd) were irradiated with either 254 or 302 nm ultraviolet (u.v.) light. The kinetics of virus inactivation revealed decreased sensitivity of IdUrd-substituted virions to irradiation with 302 nm light under all conditions examined, and with 254 nm u.v. light when substituted and control virions were irradiated at equal particle concentrations. Comparison of virus survival after irradiation measured in Vero or Xeroderma Pigmentosum (complementation group A) cells indicated that cellular repair of ultraviolet-induced lesions was not a significant factor in the observed decrease in u.v. sensitivity. IdUrd substitution altered neither the formation of ultraviolet-induced thymidine photoproducts nor the ability of irradiated virions to express delayed early viral enzymes (thymidine kinase, DNA polymerase). It is suggested that nucleocapsid proteins or the highly ordered structure of IdUrd-substituted virions play a key role in u.v. desensitization, either by the formation of non-lethal photoproducts or by the prevention of the formation of DNA-uracilyl free radicals.

Heat-shock-induced enhanced reactivation of UV-irradiated Herpesvirus

The objective of this study was to compare the ability of heat shock (HS) with that of another type of cellular stress, UV irradiation, to cause the induction of enhanced viral reactivation, a process that may represent an SOS-type repair process in mammalian cells. Studies performed to evaluate the effect of HS on growth of Vero cells revealed that HS at 45 degrees C for 45 min caused inhibition of cell growth similar to that caused by UV irradiation at 12 J/m2, but this inhibition was not observed at HS treatment for 5-15 min, or at a UV fluence of 2 J/m2. Enhanced reactivation of UV-irradiated Herpesvirus was observed in cells which had been pretreated by HS for greater than 30 min or UV at 12 J/m2. The synthesis of new proteins following HS for 15 and 45 min and UV at 12 J/m2 was examined by [35S]methionine-labeling experiments. The new synthesis of two HS proteins with molecular weights of 46 000 and 78 000 was induced by both levels of HS, but to a much greater extent at the high dose. These proteins were not detected in response to UV irradiation. These results indicate that, like UV irradiation, HS at levels inhibitory to cell growth induced enhanced viral reactivation in Vero cells. The results also suggest that at least two proteins in the HS protein family are not necessary for this response to occur.

Host cell reactivation by excision repair is error-free in human cells

Do host cell repair processes affect the mutagenesis of UV-irradiated virus in human cells? The answer was obtained by investigating the mutagenesis of UV-irradiated herpes simplex virus after the irradiated virus was grown in human cells that possess normal repair capacity (normal) or lack excision repair (XPA) or post-replication repair (XP var). Evidence is presented which indicate that XPA cells express no host cell reactivation, while XP var cells express the normal level. Viral mutagenesis was measured as the fraction of the progeny of the surviving virus capable of plaque formation in the presence of iododeoxycytidine. In the normal and XPA cells mutagenesis of the irradiated virus increased linearly with UV exposure. The UV exposure needed to yield a given mutagenesis level for virus grown in XPA cells was much lower than that for virus grown in normal cells. However, when the mutation frequencies were compared at similar virus survival levels, the data from virus grown in normal cells and in XPA cells were indistinguishable. Mutagenesis in XP var cells increased as dose squared and was similar in magnitude to that in normal cells. Thus the excision repair of normal cells which provided host cell reactivation by removing lethal UV damage also removed mutagenic lesions from the virus with the same efficiency, while the repair deficiency of XP var cells had a minor role in host cell reactivation and in mutagenesis. This demonstrates that in human cells host cell reactivation by excision repair is primarily an error-free process.

Fc and C3 receptors induced by herpes simplex virus on cultured human endothelial cells

The mechanism by which immune complexes deposit in vascular tissue is uncertain. Several human viruses, including herpes simplex virus, have recently been demonstrated to replicate in human endothelial cells. Such viruses may injure vascular tissue and could play a role in the pathogenesis of immune complex deposition. Therefore, we studied the expression of receptors for immune complexes containing IgG and C3 on endothelial cells after infection with herpes simplex virus type I.Human umbilical vein endothelial cells were incubated with (51)Cr-labeled sheep erythrocytes sensitized with IgG, IgM, or IgM plus complement. Preferential binding of IgG or complement-coated erythrocytes to uninfected endothelial monolayers was not observed. In contrast, significant binding of erythrocytes coated with IgG or IgM plus complement was observed after viral infection. Phase-contrast and scanning electron microscopy demonstrated erythrocyte adherence around the infected endothelial cells in a rosette pattern. Binding of IgG-coated erythrocytes was fully inhibited by Fc (0.31 mg/ml) but not Fab' fragments of nonimmune IgG. Binding of complement-coated cells was unaffected by the presence of IgG (1 mg/ml). With purified individual components, binding of complement-coated erythrocytes depended on the presence and was proportional to the concentration of C3. Binding of IgG-or C3-coated cells was detected beginning 4 h after infection. These studies indicate that herpes simplex virus type I infection can induce IgG and C3 receptors on human endothelial cells. These receptors may promote the deposition of immune complexes in vascular tissue after certain viral infections.

Repair and mutagenesis of herpes simplex virus in UV-irradiated monkey cells

Mutagenic repair in mammalian cells was investigated by determining the mutagenesis of UV-irradiated or unirradiated herpes simplex virus in UV-irradiated CV-1 monkey kidney cells. These results were compared with the results for UV-enhanced virus reactivation (UVER) in the same experimental situation. High and low multiplicities of infection were used to determine the effects of multiplicity reactivation (MR). UVER and MR were readily demonstrable and were approximately equal in amount in an infectious center assay. For this study, a forward-mutation assay was developed to detect virus mutants resistant to iododeoxycytidine (ICdR), probably an indication of the mutant virus being defective at its thymidine kinase locus. ICpR-resistant mutants did not have a growth advantage over wild-type virus in irraidated or unirradiated cells. Thus, higher fractions of mutant virus indicated greater mutagenesis during virus repair and/or replication. The data showed that: (1) unirradiated virus was mutated in unirradiated cells, providing a background level of mutagenesis; (2) unirradiated virus was mutated about 40% more in irradiated cells, indicating that virus replication (DNA synthesis?) became mutagenic as a result of cell irradiation; (3) irradiated virus was mutated much more (about 6-fold) than unirradiated virus, even in unirradiated cells; (4) cell irradiation did not change the mutagenesis of irradiated virus except at high multiplicity of infection. High multiplicity of infection did not lead to higher mutagenesis in unirradiated cells. Thus the data did not demonstrate UVER or MR alone to be either error-free or error-prone. When the two processes were present simultaneously, they were mutagenic.

Reactivation of herpes simplex virus in a cell line inducible for simian virus 40 synthesis

The reactivation of UV-irradiated herpes simplex virus (HSV) was investigated in irradiated and unirradiated transformed hamster cells in which infectious simian virus 40 (SV40) can be induced. Reactivation was enhanced when the cells were treated with UV light or mitomycin C prior to infection with HSV. The IV dose-response curve of this enhanced reactivation was strikingly similar to that found for induction of SV40 virus synthesis in cells treated under identical condictions. This is the first time that two SOS functions described in bacteria have been demonstrated in a single mammalian cell line.

Removal of T4 endonuclease V-sensitive sites from SV40 DNA after exposure to ultraviolet light

The induction and removal of sites sensitive to T4 endonuclease V from ultraviolet-irradiated Simian Virus 40 (SV40) Form I (supercoiled) DNA during a lytic infection of monkey CV-1 cells was investigated by agarose tube gel electrophoresis. Endonuclease-sensitive sites were induced at a rate of 0.049 sites/SV40 genome per J/m2, or 1.4 sites/1 . 10(8) daltons of DNA per J/m2. This value is similar to the yield of endonuclease-sensitive sites and pyrimidine dimers in uninfected host CV-1 cell DNA. Removal of endonuclease-sensitive sites was dose dependent and non-linear for at least 24 h after irradiation. These results suggest that SV40 DNA is subject to the excision repair mechanisms of the host cell, and that the excision of pyrimidine dimers may be one of the biochemical events underlying host cell reactivation.

Infection of UV-irradiated xeroderma pigmentosum fibroblasts by herpes simplex virus: study of capacity and Weigle reactivation

The capacity of monolayers of both normal human and xeroderma pigmentosum (XP) filbroblasts to support plaque formation by herpes simplex virus was decreased when the monolayers were ultraviolet (UV) irradiated and infected with virus. Fibroblasts of XP complementation groups A, B, and D were sensitive to UV, being 4-6 fold more sensitive than either fibroblasts of XP complementation group C or fibroblasts from a normal individual. When the monolayers were irradiated 4 days prior to infection, the capacity of normal fibroblasts to support herpes virus growth recovered, whereas the capacity of the XP strains decreased further compared to that measured when infection immediately followed irradiation. Concurrent experiments with UV-irradiated herpes virus showed that the survival of this virus did not increase when infection by irradiated virus immediately followed irradiation of the monolayers. However, if the monolayers were irradiated 4 days prior to infection, the survival of this virus increased by a factor of nearly 2. Such Weigle reactivation (WR) occurred at lower fluences to the XP fibroblasts than to normal fibroblasts, suggesting that WR results from residual cellular DNA damage left after excision repair.

Radiation enhanced reactivation of herpes simplex virus: effect of caffeine

Ultaviolet enhanced (Weigle) reactivation of UV-irradiated herpes simplex virus in UV-irradiated CV-1 monkey kidney cell monolayers was decreased by caffeine. X-ray enhanced reactivation of UV-irradiated virus in X-irradiated monolayers (X-ray reactivation) and UV- or X-ray-inactivated capacity of the cells to support unirradiated virus plaque formation were unaffected by caffeine. The results suggest that a caffeine-sensitive process is necessary for the expression of Weigle reactivation for herpes virus. Since cafeine did not significantly affect X-ray reactivation, different mechanisms may be responsible for the expression of Weigle reactivation and X-ray reactivation.

Ultraviolet enhanced reactivation of a human virus: effect of delayed infection

The ability of UV-irradiated herpes simplex virus to form plaques was examined in monolayers of CV-1 monkey kidney cells preexposed to UV radiation at different intervals before virus assay. From analysis of UV reactivation (Weigle reactivation) curves it was found that as the interval between cell UV irradiation (0-20 J/m2) and initiation of the virus assay was increased over a period of five days, (1) the capacity of the cells to support unirradiated virus plaque formation, which was decreased immediately following UV exposure to the monolayers, increased and returned to approximately normal levels within five days, and (2) at five days an exponential increase was observed in the relative plaque formation of irradiated virus as a function of UV fluence to the monolayers. For high UV fluence (20 J/m2) to the cells, the relative plaque formation by the UV-irradiated virus at five days was about 10-fold higher than that obtained from assay on unirradiated cells. This enhancement in plaque formation is interpreted as a delayed expression of Weigle reactivation. The amount of enhancement resulting from this delayed reactivation was several fold greater than that produced by the Weigle reactivation which occurred when irradiated herpes virus was assayed immediately following cell irradiation.