Herpes simplex virus latency and reactivation in isolated rat sensory neurons

The Intersection of Innate Immune Pathways with the Latent Herpes Simplex Virus Genome

Innate immune responses can impact different stages of viral life cycles. Herpes simplex virus latent infection of neurons and subsequent reactivation provide a unique context for immune responses to intersect with different stages of infection. Here, we discuss recent findings linking neuronal innate immune pathways with the modulation of latent infection, acting at the time of reactivation and during initial neuronal infection to have a long-term impact on the ability of the virus to reactivate.

Manipulation of Oxidative Stress Responses by Non-Thermal Plasma to Treat Herpes Simplex Virus Type 1 Infection and Disease

Herpes simplex virus type 1 (HSV-1) is a contagious pathogen with a large global footprint, due to its ability to cause lifelong infection in patients. Current antiviral therapies are effective in limiting viral replication in the epithelial cells to alleviate clinical symptoms, but ineffective in eliminating latent viral reservoirs in neurons. Much of HSV-1 pathogenesis is dependent on its ability to manipulate oxidative stress responses to craft a cellular environment that favors HSV-1 replication. However, to maintain redox homeostasis and to promote antiviral immune responses, the infected cell can upregulate reactive oxygen and nitrogen species (RONS) while having a tight control on antioxidant concentrations to prevent cellular damage. Non-thermal plasma (NTP), which we propose as a potential therapy alternative directed against HSV-1 infection, is a means to deliver RONS that affect redox homeostasis in the infected cell. This review emphasizes how NTP can be an effective therapy for HSV-1 infections through the direct antiviral activity of RONS and via immunomodulatory changes in the infected cells that will stimulate anti-HSV-1 adaptive immune responses. Overall, NTP application can control HSV-1 replication and address the challenges of latency by decreasing the size of the viral reservoir in the nervous system.

Neural Progenitor Cells Expressing Herpes Simplex Virus-Thymidine Kinase for Ablation Have Differential Chemosensitivity to Brivudine and Ganciclovir

Neural progenitor cell (NPC) transplants are a promising therapy for treating spinal cord injury (SCI), however, their long-term role after engraftment and the relative contribution to ongoing functional recovery remains a key knowledge gap. Selective human cell ablation techniques, currently being developed to improve the safety of progenitor cell transplant therapies in patients, may also be used as tools to probe the regenerative effects attributable to individual grafted cell populations. The Herpes Simplex Virus Thymidine Kinase (HSV-TK) and ganciclovir (GCV) system has been extensively studied in the context of SCI and broader CNS disease. However, the efficacy of brivudine (BVDU), another HSV-TK prodrug with potentially reduced bystander cytotoxic effects and in vivo toxicity, has yet to be investigated for NPC ablation. In this study, we demonstrate successful generation and in vitro ablation of HSV-TK-expressing human iPSC-derived NPCs with a >80% reduction in survival over controls. We validated an HSV-TK and GCV/BVDU synergistic system with iPSC-NPCs using an efficient gene-transfer method and in vivo ablation in a translationally relevant model of SCI. Our findings demonstrate enhanced ablation efficiency and reduced bystander effects when targeting all rapidly dividing cells with combinatorial GCV and BVDU treatment. However, for use in loss of function studies, BVDU alone is optimal due to reduced nonselective cell ablation.

Neuronal IFN signaling is dispensable for the establishment of HSV-1 latency

IFN responses control acute HSV infection, but their role in regulating HSV latency is poorly understood. To address this we used mice lacking IFN signaling specifically in neural tissues. These mice supported a higher acute viral load in nervous tissue and delayed establishment of latency. While latent HSV-1 genome copies were equivalent, ganglia from neuronal IFN signaling-deficient mice unexpectedly supported reduced reactivation. IFNβ promoted survival of primary sensory neurons after infection with HSV-1, indicating a role for IFN signaling in sustaining neurons. We observed higher levels of latency associated transcripts (LATs) per HSV genome in mice lacking neuronal IFN signaling, consistent with a role for IFN in regulating LAT expression. These data show that neuronal IFN signaling modulates the expression of LAT and may conserve the pool of neurons available to harbor latent HSV-1 genome. The data also show that neuronal IFN signaling is dispensable for the establishment of latency.

Neurons versus herpes simplex virus: the innate immune interactions that contribute to a host-pathogen standoff

Herpes simplex virus (HSV) is a prevalent neurotropic virus, which establishes lifelong latent infections in the neurons of sensory ganglia. Despite our long-standing knowledge that HSV predominately infects sensory neurons during its life cycle, little is known about the neuronal antiviral response to HSV infection. Recent studies show that while sensory neurons have impaired intrinsic immunity to HSV infection, paracrine IFN signaling can potentiate a potent antiviral response. Additionally, antiviral autophagy plays an important role in neuronal control of HSV infection. Here we review the literature of antiviral signaling and autophagy in neurons, the mechanisms by which HSV can counteract these responses, and postulate how these two pathways may synergize to mediate neuronal control of HSV infection and yet result in lifelong persistence of the virus.

Intrinsic innate immunity fails to control herpes simplex virus and vesicular stomatitis virus replication in sensory neurons and fibroblasts

Herpes simplex virus 1 (HSV-1) establishes lifelong latent infections in the sensory neurons of the trigeminal ganglia (TG), wherein it retains the capacity to reactivate. The interferon (IFN)-driven antiviral response is critical for the control of HSV-1 acute replication. We therefore sought to further investigate this response in TG neurons cultured from adult mice deficient in a variety of IFN signaling components. Parallel experiments were also performed in fibroblasts isolated concurrently. We showed that HSV-1 replication was comparable in wild-type (WT) and IFN signaling-deficient neurons and fibroblasts. Unexpectedly, a similar pattern was observed for the IFN-sensitive vesicular stomatitis virus (VSV). Despite these findings, TG neurons responded to IFN-β pretreatment with STAT1 nuclear localization and restricted replication of both VSV and an HSV-1 strain deficient in γ34.5, while wild-type HSV-1 replication was unaffected. This was in contrast to fibroblasts in which all viruses were restricted by the addition of IFN-β. Taken together, these data show that adult TG neurons can mount an effective antiviral response only if provided with an exogenous source of IFN-β, and HSV-1 combats this response through γ34.5. These results further our understanding of the antiviral response of neurons and highlight the importance of paracrine IFN-β signaling in establishing an antiviral state.

IMPORTANCE

Herpes simplex virus 1 (HSV-1) is a ubiquitous virus that establishes a lifelong latent infection in neurons. Reactivation from latency can cause cold sores, blindness, and death from encephalitis. Humans with deficiencies in innate immunity have significant problems controlling HSV infections. In this study, we therefore sought to elucidate the role of neuronal innate immunity in the control of viral infection. Using neurons isolated from mice, we found that the intrinsic capacity of neurons to restrict virus replication was unaffected by the presence or absence of innate immunity. In contrast, neurons were able to mount a robust antiviral response when provided with beta interferon, a molecule that strongly stimulates innate immunity, and that HSV-1 can combat this response through the γ34.5 viral gene. Our results have important implications for understanding how the nervous system defends itself against virus infections.

An In Vitro HSV-1 Reactivation Model Containing Quiescently Infected PC12 Cells

Advances in the understanding of the infection and reactivation process of herpes simplex type 1 (HSV-1) are generally gained by monolayer cultures or extensive and cost-intensive animal models. So far, no reliable in vitro skin model exists either to investigate the molecular mechanisms involved in controlling latency and virus reactivation or to test pharmaceuticals. Here we demonstrate the first in vitro HSV-1 reactivation model generated by using the human keratinocyte cell line HaCaT grown on a collagen substrate containing primary human fibroblasts. We integrated the unique feature of a quiescently infected neuronal cell line, the rat pheochromocytoma line PC12, within the dermal layer of the three-dimensional skin equivalent. Transmission electron microscopy, a cell-based TCID₅₀ assay, and polymerase chain reaction analysis were used to verify cell latency. Thereby viral DNA could be detected, whereas extracellular as well as intracellular virus activity could not be found. Further, the infected PC12 cells show no spontaneous reactivation within the in vitro skin equivalent. In order to simulate a physiologically comparable HSV-1 infection, we achieved a specific and pointed reactivation of quiescently HSV-1 infected PC12 cells by UVB irradiation at 1000 mJ/cm².

Induction of cellular stress overcomes the requirement of herpes simplex virus type 1 for immediate-early protein ICP0 and reactivates expression from quiescent viral genomes

Herpes simplex virus type 1 (HSV-1) mutants impaired in the activities of the structural protein VP16 and the immediate-early (IE) proteins ICP0 and ICP4 establish a quiescent infection in human fibroblasts, with most cells retaining an inactive, repressed viral genome for sustained periods in culture. To date, the quiescent state has been considered stable, since it has been reversed only by provision of herpesviral proteins, such as ICP0, not by alteration of the cell physiological state. We report that the interaction of HSV-1 with human fibroblasts can be altered significantly by transient treatment of cultures with sodium arsenite, an inducer of heat shock and oxidative stress, or gramicidin D, a toxin that selectively permeabilizes cell membranes, prior to infection. These regimens stimulated gene expression from IE-deficient HSV-1 mutants in a promoter sequence-independent manner and also overcame the replication defect of ICP0-null mutants. Reactivation of gene expression from quiescent HSV-1 genomes and the resumption of virus replication were observed following addition of arsenite or gramicidin D to cultures. Both agents induced reorganization of nuclear domain 10 structures, the sites of quiescent genomes, but appeared to do so through different mechanisms. The results demonstrate that the physiological state of the cell is important in determining the outcome of infection with IE-deficient HSV-1 and show novel methods for reactivating quiescent HSV-1 in fibroblasts with a high efficiency.

Efficient quiescent infection of normal human diploid fibroblasts with wild-type herpes simplex virus type 1

Quiescent infection of cultured cells with herpes simplex virus type 1 (HSV-1) provides an important, amenable means of studying the molecular mechanics of a nonproductive state that mimics key aspects of in vivo latency. To date, establishing high-multiplicity nonproductive infection of human cells with wild-type HSV-1 has proven challenging. Here, we describe simple culture conditions that established a cell state in normal human diploid fibroblasts that supported efficient quiescent infection using wild-type virus and exhibited many important properties of the in vivo latent state. Despite the efficient production of immediate early (IE) proteins ICP4 and ICP22, the latter remained unprocessed, and viral late gene products were only transiently and inefficiently produced. This low level of virus activity in cultures was rapidly suppressed as the nonproductive state was established. Entry into quiescence was associated with inefficient production of the viral trans-activating protein ICP0, and the accumulation of enlarged nuclear PML structures normally dispersed during productive infection. Lytic replication was rapidly and efficiently restored by exogenous expression of HSV-1 ICP0. These findings are in agreement with previous models in which quiescence was established with HSV mutants disrupted in their expression of IE gene products that included ICP0 and, importantly, provide a means to study cellular mechanisms that repress wild-type viral functions to prevent productive replication. We discuss this model in relation to existing systems and its potential as a simple tool to study the molecular mechanisms of quiescent infection in human cells using wild-type HSV-1.

Human corneal cells and other fibroblasts can stimulate the appearance of herpes simplex virus from quiescently infected PC12 cells

A two-cell system for the stimulation of herpes simplex virus type 1 (HSV-1) from an in vitro model of long-term (quiescent) infection is described. Rat pheochromocytoma (PC12) cells differentiated with nerve growth factor were infected with HSV-1 strain 17. Little, if any, cytotoxicity was observed, and a quiescent infection was established. The long-term infection was characterized by the absence of all detectable virus in the culture medium and little, if any, detectable early or late viral-gene expression as determined by reverse transcriptase PCR analysis. The presence of HSV-1 DNA was determined by PCR analysis. This showed that approximately 180 viral genomes were present in limiting dilutions where as few as 16 cells were examined. The viral DNA was infectious, since cocultivation with human corneal fibroblasts (HCF) or human corneal epithelial cells (HCE) resulted in recovery of virus from most, if not all, clusters of PC12 cells. Following cocultivation, viral antigens appeared first on PC12 cells and then on neighboring inducing cells, as determined by immunofluorescent staining, demonstrating that de novo viral protein synthesis first occurred in the long-term-infected PC12 cells. Interestingly, the ability to induce HSV varied among the cell lines tested. For example, monkey kidney CV-1 cells and human hepatoblastoma HepG2 cells, but not mouse neuroblastoma cells or undifferentiated PC12 cells, mediated stimulation. This work thus shows that (i) quiescent HSV infections can be maintained in PC12 cells in vitro, (ii) HSV can be induced from cells which do not accumulate significant levels of latency-associated transcripts, and (iii) the activation of HSV gene expression can be induced via neighboring cells. The ability of adjacent cells to stimulate HSV gene expression in neuron-like cells represents a novel area of study. The mechanism(s) whereby HCF, HCE, and HepG2 and CV-1 cells communicate with PC12 cells and stimulate viral replication, as well as how this system compares with other in vitro models of long-term infection, is discussed.

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.

Herpes simplex virus type 1 long-term persistence, latency, and reactivation in infected Burkitt lymphoma cells

The two herpes simplex virus type 1 (HSV-1) strains F and AK which differ in virus-cell interaction and in DNA organization, were used to establish persistently productive infections in Burkitt lymphoma-derived cell lines BJAB and Raji. Four such lines could be maintained over a period of three years. Like the uninfected parental lines, the persistently infected cells display a cyclic pattern of cell proliferation. The expression of HSV-1-specific antigens proved to be variable. As a consequence, virus yields also vary within a subcultivation period. Pooled human HSV antisera, when continuously present, suppress virus production (inducible latency) and support cell proliferation to higher rates. By contrast, removal of the antiserum after a certain period of cultivation leads to virus reactivation with a delay of 8 to 20 days. After cultivation periods of more than 3 to 12 weeks, replacement of HSV antiserum does no longer result in virus reactivation and even inducers fail to reactivate.

Regulation and cell-type-specific activity of a promoter located upstream of the latency-associated transcript of herpes simplex virus type 1

To identify promoter regions which control expression of the latency-associated transcript (LAT) of herpes simplex virus type 1 (HSV-1), we constructed a series of recombinant vectors in which various sequences upstream of LAT were linked to the chloramphenicol acetyltransferase gene and tested for expression efficiency by transfection into tissue culture cells. In HeLa cells no activity was observed from the region (-250 to +201) immediately surrounding the nominal 5' end of LAT, but high levels of activity were observed by using different fragments within the region -1267 to -594. This promoter activity was largely contained within the 140-base-pair region from -797 to -658 and was 20- to 50-fold stronger than typical HSV delayed-early promoters and at least as strong as the activity from the simian virus 40 (SV40) enhancer-promoter region or the HSV immediate-early 110,000-Mr (IE110K) promoter region. In human neuroblastoma cells (IMR-32), there was a dramatic switch in relative activities in favor of the LAT promoter, so that it was 45- and 200-fold stronger than the IE110K and SV40 constructs, respectively. Furthermore, optimal activity in the neuroblastoma cells required sequences within the region -1267 to -797. This region had little effect on activity in HeLa cells. We also show that the LAT promoter activity was very efficiently repressed by the IE175K protein. From internal deletion analysis, the site of repression was located within a 55-base-pair region just downstream of a potential TATA box. This region exhibited a high degree of homology with the IE175K cap site and may be a binding site for the IE175K protein.

Transient expression of human immunodeficiency virus type 1 genome results in a nonproductive infection in human fetal dorsal root ganglia glial cells

Human immunodeficiency virus type 1 (HIV-1), the etiologic agent of acquired immunodeficiency syndrome (AIDS), has been implicated in the generation of AIDS-associated neurologic dysfunction. We are currently examining the replicative processes involved in HIV-1 infection of selected human fetal neural cell populations in vitro. To determine whether infection of the human fetal dorsal root ganglia (DRG) glial cell population culminates in the production and release of infectious HIV-1, cocultivation and reverse transcriptase (RT) assays were performed. Direct assay of HIV-1 infected neural cell supernatants as well as exposure of permissive SupT1 cells to these HIV-1-infected neural cell supernatants detected no RT activity in either the HIV-1-infected DRG glial cell supernatants or the SupT1 cell supernatants. When SupT1 cells were cocultivated with the HIV-1-infected neural cells for 24-hr intervals, RT activity was detected in the SupT1 supernatants from cocultures initiated less than 2 days after infection (most likely resulting from infectious input virus) but not from cocultures initiated on 3, 5, 10, and 30 days after infection. Hybridization analysis demonstrated transient expression of HIV-1 cytoplasmic mRNA with accumulation reaching a maximum level by 2 to 3 days postinfection, declining thereafter with low, but detectable, levels at 16 days postinfection. In addition, polymerase chain reaction amplification in conjunction with DNA blot hybridization detected HIV-1-specific proviral DNA at 3 days postinfection. Cumulatively, these data suggest that HIV-1 infection of human fetal DRG glial cells culminates in a nonproductive infection with expression of at least a fraction of the virus genome but no detectable infectious virus production.

Infection of human fetal dorsal root ganglion glial cells with human immunodeficiency virus type 1 involves an entry mechanism independent of the CD4 T4A epitope

Human immunodeficiency virus type 1 (HIV-1) has been implicated in the generation of acquired immunodeficiency syndrome-associated neurological dysfunction, and it is believed that the presence of CD4 in the nervous system may be involved in the susceptibility of selected neural cell populations to HIV-1 infection. We previously demonstrated (B. Wigdahl, R. A. Guyton, and P. S. Sarin, Virology 159:440-445, 1987) that glial cells derived from human fetal dorsal root ganglion (DRG) are susceptible to HIV-1 infection and subsequently express at least a fraction of the virus genome. In contrast to HIV-1 infection of CD4+ lymphocytes, which can be blocked by treatment with monoclonal antibodies directed against the HIV-1-binding region of CD4 (T4A epitope), treatment of human fetal DRG glial cells with similar antibodies resulted in only a slight reduction in HIV-1-specific gag antigen expression. In addition, preincubation of the HIV-1 inoculum prior to infection with HIV-1-neutralizing antiserum did not reduce HIV-1 gag antigen expression in these cells. Furthermore, we were unable to detect the synthesis or accumulation of the CD4 molecule in neural cell populations derived from DRG. However, a protected CD4-specific RNA fragment was detected in RNA isolated from human fetal DRG and spinal cord tissue by an RNase protection assay with a CD4-specific antisense RNA probe. RNA blot hybridization analysis of total cellular RNA isolated from human fetal DRG and spinal cord demonstrated specific hybridization to an RNA species that comigrated with the mature 3.0-kilobase CD4 mRNA as well as two unique CD4 RNA species with relative molecular sizes of approximately 5.3 and 6.7 kilobases. Furthermore, all three CD4-related RNA species were polyadenylated when isolated from human fetal spinal cord tissue. These data suggest that HIV-1 infection of human fetal DRG glial cells may proceed via a mechanism of viral entry independent of the T4A epitope of CD4.

Protein analysis of herpes simplex virus latency in vitro established with cycloheximide

Herpes simplex virus (HSV)-specific protein synthesis was examined during establishment of HSV latency and reactivation of virus in human embryonic lung cells treated with cycloheximide and incubated at 40.5 degrees. Eight viral proteins, identified during the first two days of establishment of latency at 40.5 degrees, were undetectable by Day 3. At least two synthesized proteins were present during the maintenance phase of latency. Reactivation of HSV (viral protein 135K) was first detected in latently infected cultures between 2 and 3 hr after superinfection with human cytomegalovirus (HCMV). During this period an 82K protein with the same molecular weight as one of the HCMV immediate-early proteins (82 and 75K) was detected in the immunoprecipitates of latently infected cultures with anti-HSV serum. Thus, this HSV latency system can be used to analyze protein synthesis and clarify reactivation of HSV by HCMV superinfection.

Human herpesviruses: a consideration of the latent state

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Interaction of herpes simplex virus type 2 with a rat glioma cell line

The interaction between herpes simplex virus type 1 (HSV-1) and type 2 (HSV-2) and two neural cell lines, mouse neuroblastoma (N1E-115) and rat glioma (C6-BU-1), was investigated. N1E-115 cells were permissive to both types of HSV. In C6-BU-1 cells, on the other hand, all the HSV-1 strains tested so far showed persistent infection, and the infectious virus of HSV-2 strains disappeared spontaneously. The HSV-2-infected C6-BU-1 cells were positive for HSV-2-specific DNA sequences, virus-specific RNA, HSV-2-specific antigens and thymidine kinase activity, when no infectious virus was detected. The HSV-2 was reactivated from those C6-BU-1 cells by superinfection with murine cytomegalovirus (MCMV), but not with UV-irradiated MCMV or human cytomegalovirus. The reactivated HSV-2 was identical to the parental virus, when examined by restriction endonuclease cleavage analysis.

Human immunodeficiency virus infection of the developing human nervous system

Human immunodeficiency virus (HIV), the etiologic agent of acquired immune deficiency syndrome (AIDS) and AIDS-related complex, has recently been implicated as a factor in the development of AIDS-related neurologic dysfunction and may be responsible for an increasing number of neonatal immunologic and neurologic disorders. However, as yet there is no model system available to investigate the interaction of HIV with the developing human nervous system in vitro. To approximate the intracellular events associated with HIV infection of the human fetus nervous system we infected cells obtained by enzymatic dissociation of aborted human fetus dorsal root ganglia and their attached spinal roots and nerves. The expression of the HIV gag gene protein products (p17 and p24) was detected in a subpopulation of cells with a nonneuronal morphology, reaching a maximum within 3 days. Although 70% of the nonneuronal cells were p17- and p24-positive 3 days after infection, a majority of the cell population survived acute HIV infection, with the expression of p17 and p24 decreasing below the limit of detection by 12 days postinfection. This system may prove useful for examining the neuropathology and neurobiology of acute, persistent, or latent HIV infection of the developing human nervous system.

Nerve growth factor deprivation results in the reactivation of latent herpes simplex virus in vitro

Primary sympathetic neuronal cultures were maintained for up to 5 weeks after inoculation with herpes simplex virus (HSV) without evidence of viral infection. Upon deprivation of nerve growth factor, the cultures produced infectious HSV, indicating that the cultures harbored latent HSV. This study demonstrates a function of nerve growth factor in the maintenance of HSV latency.

Macromolecular synthesis at the early stage of herpes simplex virus type 2 (HSV-2) latency in a human neuroblastoma cell line IMR-32: repression of late viral polypeptide synthesis and accumulation of cellular heat-shock proteins

We have shown that a latent infection of herpes simplex virus type 2 (HSV-2) can be established in a human neuroblastoma cell line IMR-32 if the infected cells are cultured at 40 degrees C. In the present study, viral polypeptides and cellular heat-shock proteins which were synthesized in HSV-2 infected IMR-32 cells cultured at 40 degrees C were analyzed by polyacrylamide gel electrophoresis. It was found that the synthesis of late viral polypeptide ICP 5 was markedly reduced in the infected cells at 40 degrees C as compared with those at 37 degrees C. Although infection of IMR-32 cells with HSV-2 at 40 degrees C resulted in shutoff of cellular protein synthesis, it was found that some cellular heat-shock proteins (90, 72 and 70 kd polypeptides) were synthesized and accumulated intracellularly. These findings suggest that modification of cascade regulation of HSV-2 polypeptide synthesis and/or accumulation of heat-shock proteins may be involved in the incomplete arrest of virus growth and in survival of the infected cells, leading to the establishment of HSV-2 latency in IMR-32 cells.

Butyrate-induced reversal of herpes simplex virus restriction in neuroblastoma cells

The synthesis of herpes simplex virus (HSV) in mouse neuroblastoma cells (NB, clone 41A3) is restricted. There was a disappearance of infectious virus upon serial passage of infected cells. NB cells treated with sodium-n-butyrate for 24 hr before infection synthesized 200-2000 times more HSV than untreated cells. Infectious center assays demonstrated that the number of cells capable of producing HSV was increased as a result of butyrate pretreatment. Although host protein synthesis was inhibited by HSV infection, viral-induced protein and DNA syntheses were not detected in the absence of butyrate. Cycloheximide blocked the induction of permissiveness by butyrate suggesting that a protein(s) was responsible for allowing HSV synthesis in NB cells. Regulatable host factors involved in HSV replication in neural cells can be studied in the system described.

Herpes simplex virus type 1 persistence and latency in cultured rabbit corneal epithelial cells, keratocytes, and endothelial cells

Cell cultures of rabbit corneal epithelium, keratocytes, and endothelium were used to determine the lytic cycle of herpes simplex virus type 1. Viral growth was fastest in epithelial cells. A novel HSV-1 in-vitro latency system was established in the three distinct cell types. Cell cultures were inoculated at low multiplicities of infection with HSV-1. Temperature manipulation alone was used to induce and reactivate latent HSV-1 infections. The presence of cellular stress proteins was demonstrated at supraoptimal temperatures. All cell types were capable of maintaining latent viral infections under these conditions. Viral persistence was present in 20% of epithelial cell cultures at supraoptimal temperatures, but not in keratocyte cultures or endothelial cell cultures.

A latent infection of herpes simplex virus type 2 in a human neuroblastoma cell line IMR-32

Human neuroblastoma (IMR-32) cells were infected with herpes simplex virus type 2 (HSV-2) at a multiplicity of infection (MOI) of 2 plaque-forming units (PFU)/cell and were cultured at 40 degrees C for 14 days. Then neither infectious virus particles nor virus capsids were detected in these cells whereas the presence of virus-specific antigens was observed by immunofluorescent antibody staining technique in 16.9 +/- 3.2 per cent of the infected cell population. When the cultivation temperature was shifted down from 40 degrees C to 35 degrees C, reactivation of virus growth occurred after lag periods of 2-9 days. These findings indicate that the IMR-32 cells can be latently infected with HSV-2 at 40 degrees C and that virus growth may be inhibited at the level of synthesis of virus-specific macromolecules or at some step preceding nucleocapsid formation.

Prolonged herpes simplex virus latency in vitro after treatment of infected cells with acyclovir and human leukocyte interferon

We previously demonstrated that herpes simplex virus type 1 (HSV-1) can be established in a latent form in vitro by the treatment of HSV-infected human cells with (E)-5-(2-bromovinyl)-2'-deoxyuridine (BVDU) in combination with human leukocyte interferon (IFN-alpha). We now report that the substitution of BVDU with 9-[(2-hydoxyethoxy)methyl]guanine (acyclovir; ACV) during a combined treatment with IFN-alpha inhibited HSV-1 replication and established in vitro virus latency that could be maintained for a longer period after inhibitor removal and a continued incubation at 37 degrees C. By contrast, the treatment of HSV-1-infected cells with combined IFN-alpha and 9-(1,3-dihydroxy-2-propoxymethyl)guanine, a congener of ACV, failed to establish in vitro virus latency. Furthermore, none of these inhibitors used alone was sufficient to establish in vitro virus latency. The use of nucleoside analogs differing from BVDU in their modes of action has enabled us to initiate studies designed to extend in vitro virus latency.

Amplification of herpes simplex virus resistance in mouse neuroblastoma (Cl300) cells

Clones of mouse neuroblastoma (Cl300) cells with increased resistance to herpes simplex virus (HSV) were obtained among survivors after prolonged exposure of partially HSV resistent Cl300 cells to successively increasing multiplicities of infection (MOI) of HSV. The increased restrictedness to HSV of these Cl300 R clones (Cl300 RI and Cl300 RII) as compared to the parental Cl300 cells was demonstrated by a tolerance to higher MOIs of HSV, judged by the appearance of cytopathic effects; by lower yields of progeny virus; and by higher activities of a non-interferon HSV inhibitor. Morphological appearance, cellular growth rate as well as HSV adsorptive capacity of the Cl300 R cells did not differ from that of Cl300 cells. Neither was virus penetration affected. These neuroblastoma Cl300 R cells, demonstrating an amplified resistance to HSV, might serve useful in studies on the regulation of virus replication in HSV latency establishment in neurons.

Herpes simplex virus latency in a hyperresistant clone of mouse neuroblastoma (Cl300) cells

Herpes simplex virus (HSV) hyperresistant neuroblastoma cells (clone Cl300 RII) were latently infected with HSV-1 if cultured in presence of HSV-neutralizing antibody for one or two passages after infection and then passaged further without antibody. By superinfecting HSV-1 latently infected Cl300 RII cells with HSV-2, progeny virus with HSV-1 characteristics was regularly rescued. Such retrieval of HSV-1 decreased with passage of the latently infected cells.

Herpes simplex virus latency in isolated human neurons

Herpes simplex virus is most probably maintained in the ganglion neurons of the peripheral nervous system of humans in a latent form that can reactivate to produce recurrent disease. As an approximation of this cell-virus interaction, we have constructed a herpes simplex virus latency in vitro model system using human fetus sensory neurons as the host cell. Human fetus neurons were characterized as neuronal in origin by the detection of the neuropeptide substance P and the neuron-specific plasma membrane A2B5 antigen. Virus latency was established by blocking complete expression of the virus genome by treatment of infected human neurons with a combination of human leukocyte interferon and (E)-5-(2-bromovinyl)-2'-deoxyuridine for 7 days. After removal of inhibitors, virus latency was maintained for at least 9 days. This in vitro model will provide a system to analyze, in a primary human neuron, the state of the herpes simplex virus genome during establishment and maintenance of experimental latency.

Analysis of the herpes simplex virus genome during in vitro latency in human diploid fibroblasts and rat sensory neurons

We have previously designed in vitro model systems to characterize the herpes simplex virus type 1 (HSV-1) genome during in vitro virus latency. Latency was established by treatment of infected human embryo lung fibroblast (HEL-F) cells or rat fetal neurons with (E)-5-(2-bromovinyl)-2'-deoxyuridine and human leukocyte interferon and was maintained by increasing the incubation temperature after inhibitor removal. Virus was reactivated by reducing the incubation temperature. We have now examined the HSV-1-specific DNA content of latently infected HEL-F cells and rat fetal neurons treated with (E)-5-(2-bromovinyl)-2'-deoxyuridine and human leukocyte interferon and increased temperature. The HEL-F cell population contained, on an average, between 0.25 and 0.5 copies of most, if not all, HSV-1 HindIII and XbaI DNA fragments per haploid cell genome equivalent. In contrast, the latently infected neurons contained, on an average, 8 to 10 copies per haploid cell genome equivalent of most HSV-1 BamHI DNA fragments. There was no detectable alteration in size or molarity of the HSV-1 terminal or junction DNA fragments obtained by HindIII, XbaI, or BamHI digestion of the latently infected neuron or HEL-F cell DNA, as compared with digestion of a reconstruction mixture of purified HSV-1 virion and HEL-F cell DNAs. These data suggest that the predominant form of the HSV-1 genome in either latently infected cell population is nonintegrated, linear, and nonconcatameric.