The targeting of primary effusion lymphoma cells for apoptosis by inducing lytic replication of human herpesvirus 8 while blocking virus pro
http://www.100md.com
《血液学杂志》
the Winship Cancer Institute, Emory University, Atlanta, GA.
Abstract
Primary effusion lymphoma (PEL) is a B-cell lymphoma in which human herpesvirus-8 (HHV-8) is found within all tumor cells and represents a target for selectively destroying tumor cells. HHV-8 is latent in most PEL cells and, hence, resistant to antiviral agents that inhibit lytic replication. We demonstrate that PEL cell lines containing HHV-8 without and with coinfection with Epstein-Barr virus responded to the antiseizure medication valproate with entry into the lytic cascade and production of infectious virus. Minimal cell death occurred when noninfected BL-41 cells were incubated with valproate, whereas apoptosis occurred in response to valproate in PELs that supported lytic replication of HHV-8. The anti-viral agents ganciclovir and phosphonoformic acid (PFA) blocked valproate-induced production of infectious virus without blocking entry into the lytic cascade, and apoptosis occurred at levels that were as high as when virus production was not blocked. Ganciclovir and PFA also prevented most valproate-induced expression of the late lytic viral transcript open reading frame 26 (ORF-26), but they did not block the induction of either viral interleukin-6 (vIL-6) or viral G protein-coupled receptor (vGPCR). These studies provide evidence that incubation of PELs with valproate in the presence of ganciclovir or PFA can selectively target tumor cells for apoptosis without increasing viral load.
Introduction
Human herpesvirus 8 (HHV-8; also known as Kaposi sarcoma herpesvirus or KSHV) is a large double-stranded DNA virus of the gamma herpesvirus family that is involved in the pathogenesis of both Kaposi sarcoma (KS) and primary effusion lymphoma (PEL).1,2 B lymphocytes serve as a reservoir for HHV-8, with viral infection persisting throughout the lifetime of the host.3-5 HHV-8-infected B lymphocytes can undergo malignant transformation, resulting in PELs.6-9 These rare B-cell lymphomas present as effusions without major lymph node or solid organ involvement.7,9 PEL cells are universally infected with HHV-8, and they are often coinfected with Epstein-Barr virus (EBV).10,11 They also contain multiple chromosomal abnormalities.11,12
The ability of HHV-8 to enter a latent state plays a key role in the development of HHV-8-associated tumors. During latency, the few viral proteins that are expressed help replicate the viral genome during cellular replication and ensure the survival of the infected population of cells.2,13 The disruption of important regulatory pathways that occurs during latency makes cells more susceptible to acquiring additional genetic or epigenetic changes that promote tumor development. All latently infected cells express the latency-associated nuclear antigen (LANA), a protein that is required for the replication of the viral episome and tethers it to cellular chromosomes during cell division.14-16 This ensures that the viral episome is maintained during cellular division so that the HHV-8 undergoes clonal expansion as latently infected cells replicate. LANA also disrupts the function of the tumor suppressor proteins p53 and Rb.17,18 Latently infected cells also express viral cyclin (v-cyclin) and viral Fas-associated death domain (FADD)-like interleukin-1-converting enzyme inhibitory protein (v-FLIP).19,20 The expression of v-cyclin contributes to unregulated proliferation of cells by activating cyclin dependent kinase 4 (cdk4) and cdk6, and it is resistant to inhibition by p21 and p16, unlike its cellular counterpart cyclin D.21-23 The v-FLIP protein inhibits apoptosis by activating the transcription factor nuclear factor-B (NF-B) and by preventing the activation of caspase 8.24-26 Together, the few viral genes that are expressed in latently infected cells enhance cell proliferation and reduce cell death.
The presence of HHV-8 in all PEL and KS cells3 provides a target for selective destruction of tumor cells without harming uninfected normal cells. HHV-8 is latent in most PEL cells but has the potential to switch to lytic replication.27,28 Lytic replication involves a complex cascade of viral gene expression to produce proteins required for replicating viral DNA and packaging it into infectious virions. Viral gene products expressed during lytic replication inhibit cellular gene expression and cellular replication, thereby conserving resources for viral production.29-31 Viral DNA polymerase is exclusively expressed during the lytic cascade and is required for lytic replication of viral DNA and expression of late lytic viral gene products.32-34 At appropriate concentrations, both ganciclovir and phosphonoformic acid (PFA, clinically known as foscarnet) can inhibit viral DNA polymerase, thereby preventing production of infectious virus.35 Ganciclovir is an acyclic nucleoside that undergoes phosphorylation by viral enzymes expressed during the lytic cascade. Phosphorylated ganciclovir inhibits viral DNA polymerase and can also be incorporated into cellular and viral DNA, leading to premature chain termination,36 whereas PFA is inhibitory to viral DNA polymerase without modification.37-39
In this study, we explored the consequences of combining viral DNA polymerase inhibitors with valproate (2-propylpentanoate). Valproate is clinically used to control partial and generalized epileptic seizures and neuropathic pain and to stabilize mood,40,41 and it is structurally and functionally similar to butyrate in its ability to induce lytic replication of HHV-8.42 We demonstrate that valproate inhibited proliferation and induced apoptosis of BCBL-1 and JSC-1 cells, PEL cell lines that are infected with HHV-8 in the absence and presence of coinfection with EBV, respectively.43 In contrast, valproate was nontoxic to a noninfected Burkitt lymphoma B-cell line. The valproate-induced production of infectious HHV-8 from BCBL-1 and JSC-1 cells was blocked by either ganciclovir or PFA, whereas apoptosis continued to occur. These studies indicate that the combined use of valproate and viral DNA polymerase inhibitors can selectively target HHV-8-infected cells for apoptotic death without increasing the viral load.
Materials and methods
Cell culture
BCBL-1 cells (HHV-8-positive, EBV-negative) and BL-41 cell line (HHV-8-negative, EBV-negative) were obtained from the National Institutes of Health AIDS Research and Reference Program (Rockville, MD). JSC-1 cells were kindly provided by Dr Richard Ambinder (Johns Hopkins University, Baltimore, MD). All cells were maintained in RPMI 1640 medium supplemented with 10% fetal calf serum, 2 mM L-glutamine, 100 U penicillin, and 10 U streptomycin. A reporter cell line for quantification analysis of infectious HHV-8, T1H6,44 was maintained in Dulbecco modification of Eagle medium (Cellgro, Herndon, VA) supplemented with 10% fetal bovine serum, 2 mM L-glutamine, 200 U/mL penicillin, 10 U/mL streptomycin, and 50 μg/mL hygromycin B (Invitrogen, Carlsbad, CA) and split 1:10 every 3 to 4 days. Valproate (2-propylpentanoic acid), butyrate, ganciclovir, and phosphonoformic acid were purchased from Sigma-Aldrich (St Louis, MO).
Northern blot analysis
Total cellular RNA was isolated using Trizol (GibcoBRL, Grand Island, NY) and was size fractionated on a 1% agarose/formaldehyde gel.45 RNA was transferred to nitrocellulose and covalently linked by ultraviolet irradiation using a Stratalinker (Stratagene, La Jolla, CA) and by baking in vacuo for 2 hours at 80°C. DNA probes for viral interleukin 6 (vIL-6),46 viral G protein-coupled receptor (vGPCR), open reading frame 26 (ORF-26), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH)47 were radiolabeled using an oligolabeling kit (Stratagene) with 32P deoxycytidine triphosphate (dCTP) according to the manufacturer's recommendations. Hybridizations were performed at 42°C in 20 x standard saline citrate (SSC), 10% sodium dodecyl sulfate (SDS), 50 x Denhart, 100 μg/mL denatured salmon sperm DNA, 50% formamide, 10% dextran sulfate, and 100 ng 32P-dCTP-labeled DNA at a specific activity of 1 x 108 cpm/μg. Nitrocellulose was washed with a final stringency of 0.2 x SSC in 0.1% SDS at 55°C. Blots were serially probed for the genes indicated, and the nitrocellulose was stripped using boiling water prior to rehybridization with other probes. Autoradiography was performed with an intensifying screen at –80°C.
Immunofluorescence
Cytospin preparations from BCBL-1 and JSC-1 cells were air-dried and fixed in ice-cold acetone. Slides were rehydrated with phosphate-buffered saline (PBS) for 10 minutes. The terminal deoxynucleotidyl transferase (TdT) nick end labeling (TUNEL) assay was done according to the manufacturer's recommendation (DeadEnd Fluorometric TUNEL System; Promega, Madison, WI). After the terminal deoxynucleotidyl transferase (TdT) enzyme incubation and the termination of the reaction with 2 x SSC, slides were washed 3 times with PBS and subjected to immunohistochemical staining for DNA polymerase processivity factor (PPF) using a mouse monoclonal antibody to PPF, the product of ORF-59 (anti-ORF-59, 1:100; Advanced Biotechnologies, Columbia, MD). Slides were blocked with goat serum for 10 minutes at 37°C prior to overnight incubation at 4°C in a wet chamber with anti-ORF-59 in 5% goat serum. Slides were then washed 3 times and incubated for 45 minutes at 37°C with goat anti-mouse Alexa Fluor 567 (Molecular Probes, Eugene, OR). Slides were washed 3 times with PBS and then mounted with antifading agent. Imaging was performed using a Nikon Eclipse E-800 microscope equipped with an oil immersion 100x/1.3 objective lens and an Optronics MagnaFire S99800 digital camera. The emission patterns of the 2 fluorescences were collected separately. Identical exposure times were used for data acquisition from each slide for the individual fluorescent probes.
Assessment of cell viability and apoptosis
Cell viability was determined by trypan blue exclusion and direct counting with a hemacytometer. Apoptosis was determined by using the DeadEnd Fluorometric TUNEL System (Promega) according to the manufacturer's recommendation. Cells (2 x 106) were fixed in ice-cold 1% formaldehyde, washed with PBS, and permeabilized with 70% ethanol for 24 hours at -20°C. The fragmented DNA of apoptotic cells was identified by catalytically incorporating fluorescein-12-dUTP at 3'-OH DNA ends, using the enzyme TdT in TdT incubation buffer. As a control, cells were treated with incubation buffer that did not contain TdT enzyme. Cells were analyzed using a FACScan flow cytometer (Becton Dickinson, San Jose, CA).
Assay for infectious HHV-8 production using the T1H6 cell line
The T1H6 reporter cell line contains the lacZ gene under a control of the PAN promoter and responds to infection with HHV-8 in a sensitive and quantitative manner that accurately assesses the amount of infectious HHV-8 present.44,48,49 Briefly, 8 x 104 T1H6 cells/well were seeded in 48-well plates in triplicate. The next day, 200 μL medium from PEL cells was assayed for infectious virus by filtering it through a 0.45-μm filter and then adding it to T1H6 cells in the presence of 8 μg/mL polybrene (Sigma, St Louis, MO). Plates with T1H6 cells were centrifuged at 400g for 30 minutes at room temperature and incubated at 37°C for 1.5 hours. The medium was changed, and cells were incubated for 2 days at 37°C. After 3 freeze-thaw cycles with 50 μL PBS, cell lysates were harvested, and their -galactosidase activities were measured by Luminescent -galactosidase assay (Clontech, Palo Alto, CA) using LUMIstar Galaxy luminometer (BMG LabTechnologies, Durham, NC). For the standard curve, dilution series of infectious virus were used as well as serial dilutions of the -galactosidase.
Results
Changes in cell number and production of infectious virus resulting from incubation with valproate
There is extensive clinical information on the safety and toxicity of valproate in patients treated for neurologic conditions. Plasma concentrations during chronic oral treatment typically range from 0.28 mM to 0.69 mM.40 We previously demonstrated that a concentration of valproate between 0.03 and 3 mM induced the expression of lytic cycle-associated HHV-8 genes.42 Here, we examined changes in cell proliferation, cell survival, and production of infectious virus using a concentration of valproate that is clinically encountered. When BCBL-1 cells were incubated with 0.6 mM valproate, there was an inhibition of the increase in cell number that occurred over time that was very similar to the inhibition that occurred using 0.6 mM butyrate (Figure 1A). Untreated cells showed a more than 7-fold increase in cell number over 3 days, and then cell numbers plateaued. When valproate was present, the plateau occurred much earlier, with a more than 50% reduction in total cell number compared with control cells. The TUNEL assay was used to assess the role of apoptosis in the changes in cell number. Incubation with valproate caused a time-dependent increase in the percentage of cells undergoing apoptosis, with 40% of cells being TUNEL-positive on day 2 and more than 70% by day 3 (Figure 1B). In contrast, approximately 10% of control cells were undergoing apoptosis, and this remained relatively constant over a 4-day period.
A number of steps need to be successfully completed in the lytic cascade of HHV-8 for infectious virus to be produced. We have previously reported that incubation with 3 mM butyrate induces apoptosis prior to completion of virus production, whereas apoptosis occurs at later time points that do not prevent the production of intact virions when the concentration of butyrate is reduced to 0.3 mM.46 We thus compared the amount of infectious virus that was present in the conditioned medium at various time points after incubation with either 0.6 mM valproate or 0.3 mM butyrate. The amount of extracellular infectious virus in conditioned medium was determined by using the T1H6 reporter cell line that contains an HHV-8 Rta-dependent promoter linked to a -galactosidase gene, and the expression of -galactosidase is directly proportional to the amount of infectious virus present.44,48,49 There was a low level of infectious virus detected in the conditioned medium from BCBL-1 cells 3 days following stimulation with either valproate or butyrate, whereas there was no detectable infectious virus in conditioned medium from control cells (Figure 1C). By day 4, the amount of infectious virus in the conditioned medium showed a sharp increase in response to both valproate and butyrate, with levels peaking by day 5. There was no further increase in the amount of infectious virus in the medium during longer incubations (data not shown). When BCBL-1 cells were incubated with 0.6 mM valproate, more infectious virus was produced than when cells were incubated with 0.3 mM butyrate (Figure 1C). Thus, the apoptosis that resulted from incubation with valproate did not prevent the release of infectious virus, suggesting that apoptosis occurred after the completion of virus production in many of the cells.
Sensitivity of HHV-8-infected and uninfected B-cell lines to valproate and antivirals
A nonvirally infected Burkitt lymphoma B-cell line (BL41) was compared with HHV-8-infected BCBL-1 cells to determine whether the apoptosis that resulted from valproate was due to cellular changes independent of HHV-8. For all conditions examined, incubation with valproate did not significantly reduce the number of BL41 cells (Figure 2A), whereas there was more than a 50% reduction in cell number when BCBL-1 cells were incubated with valproate (Figure 2B). Ganciclovir at 2 and 20 μM was well tolerated by both cell types, whereas 200 μM ganciclovir was toxic to both cell types, causing a 70% reduction in the number of BL41 cells and a 50% reduction in the number of BCBL-1 cells (Figure 2A-B). The cell death resulting from ganciclovir at 200 μM was not related to the antiviral effects of ganciclovir since the BL41 cells were not virally infected. PFA at either 100 or 750 μM was well tolerated by BL41 cells, but there was a 25% reduction in BCBL-1 cell number resulting from incubation with 750 μM PFA. The reduction occurred independent of valproate-induced entry into the lytic cascade.
Effect of ganciclovir and PFA on valproate induced mRNA expression
Concentrations of ganciclovir and PFA that are effective at blocking viral DNA polymerase should inhibit the expression of late lytic viral mRNAs, a group of viral transcripts that are dependent on lytic viral DNA replication for expression.1,5 Northern blot analysis demonstrated that incubation with valproate for 4 days induced high levels of expression of the late lytic transcript ORF-26 (Figure 3). Both ganciclovir and PFA caused a concentration-dependent reduction in ORF-26 expression. Incubation with 750 μM PFA blocked all valproate-induced expression of ORF-26, whereas expression of ORF-26 was reduced but not fully blocked by ganciclovir at 2 to 20 μM or PFA at 100 μM. Valproate also induced high levels of expression of vIL-6 and vGPCR, but neither ganciclovir nor PFA prevented their induction. This was expected since viral transcripts expressed early in the lytic cascade are not dependent on viral DNA polymerase for expression. The slight reduction in the amount of vIL-6 and vGPCR that occurred when valproate-stimulated cells were incubated with PFA of 750 μM was accompanied by less GAPDH mRNA, suggesting that it was due to loading differences in mRNA or the toxic effects that were noted at this concentration. The levels of the cellular mRNA GAPDH decreased when cells were incubated with valproate both in the absence and presence of ganciclovir and PFA, consistent with the known inhibition of cellular gene transcription that occurs during lytic replication.30,31
Inhibition of valproate-induced production of HHV-8 by ganciclovir and PFA
Inhibition of ORF-26 expression provided evidence that PFA at 750 μM was the most effective inhibitor of valproate-induced production of infectious virus, with 20 μM ganciclovir nearly as effective. We explored the relative efficacy of the agents in more detail by using the T1H6 reporter cell line to assess the amount of infectious virus released by BCBL-1 cells since viral particles can often be defective and noninfectious. When BCBL-1 cells were incubated with valproate for 5 days, there was a large increase in the amount of infectious virus in the conditioned medium, leading to a large increase in reporter cell activity (Figure 4). When either ganciclovir (2 or 20 μM) or PFA (100 or 750 μM) were present during incubation with valproate, the increased production of infectious virus was almost completely blocked. Thus, the low level of late gene expression that was observed when valproate-stimulated BCBL-1 cells were incubated with ganciclovir at 2 to 20 μm or PFA at 100 μM was accompanied by minimal release of infectious virus.
Valproate-induced apoptosis in BCBL-1 cells incubated with ganciclovir and PFA
Incubation of BCBL-1 cells with valproate for 3 days increased the percentage of cells undergoing apoptosis by approximately 4-fold (Figure 5). When ganciclovir or PFA was present to inhibit viral DNA replication and late lytic gene expression, there was no reduction in the amount of apoptosis that occurred (Figure 5A-B), indicating that valproate-induced apoptosis was not dependent on viral DNA replication or on the expression of late viral gene products. Incubation with valproate for 4 days induced nearly the entire population of BCBL-1 cells to enter the lytic phase of viral replication, reflected by the expression of DNA polymerase processivity factor (PPF), a protein encoded by ORF-59 that is exclusively expressed during the lytic cascade50 (Figure 5C). Most cells that were expressing PPF were undergoing apoptosis at this time point, and the apoptosis was not blocked by ganciclovir (Figure 5C) or PFA (data not shown).
While BCBL-1 cells are infected with HHV-8 and not with EBV, most PELs, including JSC-1 cells, are coinfected with both HHV-8 and EBV.51 We examined the response of JSC-1 cells to valproate in the absence and presence of antivirals to determine whether coinfected PELs were also susceptible to valproate-induced lytic replication and apoptosis. There was a time-dependent increase in cell number when JSC-1 cells were incubated under control conditions, and the increase in cell number was reduced by incubation with valproate at either 0.6 or 1.2 mM (Figure 6A). Incubation with valproate induced the accumulation of infectious virus in the medium, with more virus produced when cells were incubated with 1.2 mM valproate than with 0.6 mM valproate (Figure 6B). Both ganciclovir and PFA effectively blocked the valproate-induced production of infectious virus. JSC-1 cells that were incubated with valproate underwent apoptosis, and inhibition of virus production did not prevent valproate-induced apoptosis (Figure 6C). Immunofluorescent analysis demonstrated that the majority of JSC-1 cells incubated with valproate expressed PPF, and the PPF-positive cells became TUNEL positive, similar to the BCBL-1 cells shown in Figure 5C (data not shown). Thus, the HHV-8 in PELs responded to valproate with entry into the lytic cascade and apoptosis irrespective of whether EBV was present or absent.
Discussion
These studies demonstrate that incubation with valproate induced HHV-8 in PEL cells to enter the lytic cascade, leading to production of infectious virus and the death of most cells by apoptosis. Minimal cell death occurred when noninfected BL-41 cells were incubated with valproate, providing evidence that the apoptosis that occurred in PEL cells was more closely linked to the lytic replication of HHV-8 than to cellular changes induced by valproate. The induction of lytic replication of HHV-8 that occurred with valproate was seen with PELs both with and without coinfection with EBV. Both ganciclovir and PFA blocked valproate-induced production of HHV-8 without blocking entry into the lytic cascade, and apoptosis continued to occur at levels that were as high as when virus production was not blocked. This indicates that the apoptosis was not dependent on replication of viral DNA or on completion of the lytic cascade.
Apoptosis represents an important mechanism used by the host to eliminate virally infected cells.52-55 There are viral gene products expressed during both latent and lytic replication that inhibit apoptosis,17,20,56-60 yet these did not prevent apoptosis in cells supporting lytic replication of HHV-8. Immunofluorescent studies examining PPF demonstrated that a few cells that spontaneously entered the lytic cascade were TUNEL positive, whereas surrounding cells that did not express PPF were TUNEL negative. This indicates that apoptosis occurred in cells that entered the lytic cascade independent of incubation with valproate. Similarly, lytic replication induced by either 12-O-tetradecanoylphorbol-13-acetate (TPA) or butyrate leads to apoptosis of BCBL-1 cells.46,49,61 More transcripts and proteins are expressed at high levels during the lytic cascade than during latency, and this increases the likelihood of detection by cellular defenses.46,49,61,62 Apoptosis occurred when viral late gene expression was blocked, indicating that changes occurring early in the lytic cascade were sufficient to induce apoptosis despite expression of viral proteins with antiapoptotic activity. The transient expression of some antiapoptotic proteins limits their ability to suppress apoptosis. For example, overexpression of viral interferon (IFN) regulatory factor 1 (vIRF-1) can suppress apoptosis,56,63 but vIRF-1 is expressed relatively early in the lytic cascade, and its expression is transient because of a short half-life, thereby limiting its ability to block apoptosis.49 The increase in viral DNA that occurs during lytic replication is not required for the apoptotic response since inhibition of viral DNA replication did not reduce the level of apoptosis that occurred. This suggests that viral transcripts and/or proteins expressed during the lytic cascade were responsible for triggering apoptosis.
The concentration of valproate that we used to induce lytic replication of HHV-8 was in the range that is present in the plasma of patients treated with valproate for neurologic diseases.40 This indicates that patients taking valproate who are latently infected with HHV-8 are at risk for lytic reactivation of HHV-8 and production of infectious virus unless virus production is blocked. This could increase the likelihood of developing HHV-8-associated diseases such as KS since the development of new KS lesions is more likely to occur when circulating virus is detected.64,65 Valproate and butyrate are very similar in structure and display nearly identical dose-response curves for lytic gene induction.42 Both valproate and butyrate function as histone deacetylase inhibitors and affect the expression of both cellular and viral genes.66-69 BCBL-1 cells respond to high concentrations of butyrate and valproate with apoptosis prior to production of infectious virus, but this does not occur in response to TPA.46 This suggests that the apoptosis that results from valproate and butyrate has a cellular component that augments the apoptosis triggered by lytic replication, consistent with the ability of these agents to induce apoptosis in some nonvirally infected cells.66,67,69-71
The apoptosis that occurs as a consequence of valproate-induced lytic reactivation represents an opportunity to selectively kill virally infected cells while blocking production of infectious virus. PFA directly inhibits the viral DNA polymerase by binding to the pyrophosphate-binding site at concentrations that do not affect the cellular polymerase,72-74 whereas ganciclovir must first undergo phosphorylation by either HHV-8 viral thymidine kinase (ORF-21) or viral phosphotransferase (ORF-36), proteins that are expressed exclusively during the lytic cascade.37 The phosphorylated ganciclovir can then undergo additional phosphorylation by cellular enzymes, thereby creating an acyclic nucleic acid that can be incorporated into either viral or cellular DNA. PFA was as effective at preventing viral production as ganciclovir, and apoptosis continued to occur. This indicates that incorporation of acyclic nucleotides into DNA is not required for induction of apoptosis, suggesting that the apoptosis occurs in large part as a cellular response to viral products expressed during the lytic cascade.
The tumor cells for both PEL and KS harbor HHV-8 that is primarily latent. Pharmacokinetic studies of valproate, PFA, and ganciclovir demonstrate that concentrations that were effective in this study can be safely achieved in patients.40,75,76 This suggests that combined treatment with valproate and antiviral agents could selectively target tumors that are infected with HHV-8 for destruction without killing noninfected cells. Either PFA or ganciclovir should prevent valproate-induced production of HHV-8 without preventing apoptosis, and this should limit any long-term problems associated with virus dissemination or paracrine responses to viral proteins such as vIL-6 that are expressed early in the lytic cascade.
Footnotes
Prepublished online as Blood First Edition Paper, February 1, 2005; DOI 10.1182/blood-2004-09-3569.
Supported by the US Public Health Service (grant RO-1 CA 79402).
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
References
Moore PS, Chang Y. Kaposi's sarcoma-associated herpesvirus. In: Fields B, Knipe D, Howley P, eds. Field's Virology. Vol 2. 4th ed. Philadelphia: Lippencott-Raven Publishers; 2001: 2803-2833.
Viejo-Borbolla A, Ottinger M, Schulz TF. Human herpesvirus 8: biology and role in the pathogenesis of Kaposi's sarcoma and other AIDS-related malignancies. Curr Infect Dis Rep. 2003;5: 169-175.
Dupin N, Fisher C, Kellam P, et al. Distribution of human herpesvirus-8 latently infected cells in Kaposi's sarcoma, multicentric Castleman's disease, and primary effusion lymphoma. Proc Natl Acad Sci U S A. 1999;96: 4546-4551.
Matsushima AY, Strauchen JA, Lee G, et al. Post-transplantation plasmacytic proliferations related to Kaposi's sarcoma-associated herpesvirus. Am J Surg Pathol. 1999;23: 1393-1400.
Roizman B, Philip PE. The family herpesviridae: a brief introduction. In: Fields B, Knipe D, Howley P, eds. Field's Virology. Vol 2. 4th ed. Philadelphia, PA: Lippencott-Raven; 2001: 2381-2397.
Mesri EA, Cesarman E, Arvanitakis L, et al. Human herpesvirus-8/Kaposi's sarcoma-associated herpesvirus is a new transmissible virus that infects B cells. J Exp Med. 1996;183: 2385-2390.
Cesarman E, Knowles DM. The role of Kaposi's sarcoma-associated herpesvirus (KSHV/HHV-8) in lymphoproliferative diseases. Semin Cancer Biol. 1999;9: 165-174.
Carbone A, Cilia AM, Gloghini A, et al. Establishment and characterization of EBV-positive and EBV-negative primary effusion lymphoma cell lines harbouring human herpesvirus type-8. Br J Haematol. 1998;102: 1081-1089.
Cesarman E, Nador RG, Aozasa K, Delsol G, Said JW, Knowles DM. Kaposi's sarcoma-associated herpesvirus in non-AIDS related lymphomas occurring in body cavities. Am J Pathol. 1996; 149: 53-57.
Callahan J, Pai S, Cotter M, Robertson ES. Distinct patterns of viral antigen expression in Epstein-Barr virus and Kaposi's sarcoma-associated herpesvirus coinfected body-cavity-based lymphoma cell lines: potential switches in latent gene expression due to coinfection. Virology. 1999; 262: 18-30.
Drexler HG, Uphoff CC, Gaidano G, Carbone A. Lymphoma cell lines: in vitro models for the study of HHV-8+ primary effusion lymphomas (body cavity-based lymphomas). Leukemia. 1998;12: 1507-1517.
Gaidano G, Capello D, Fassone L, et al. Molecular characterization of HHV-8 positive primary effusion lymphoma reveals pathogenetic and histogenetic features of the disease. J Clin Virol. 2000; 16: 215-224.
Collins CM, Medveczky PG. Genetic requirements for the episomal maintenance of oncogenic herpesvirus genomes. Adv Cancer Res. 2002;84: 155-174.
Kedes DH, Lagunoff M, Renne R, Ganem D. Identification of the gene encoding the major latency-associated nuclear antigen of the Kaposi's sarcoma-associated herpesvirus. J Clin Invest. 1997;100: 2606-2610.
Ballestas ME, Chatis PA, Kaye KM. Efficient persistence of extrachromosomal KSHV DNA mediated by latency-associated nuclear antigen. Science. 1999;284: 641-644.
Cotter MA II, Robertson ES. The latency-associated nuclear antigen tethers the Kaposi's sarcoma-associated herpesvirus genome to host chromosomes in body cavity-based lymphoma cells. Virology. 1999;264: 254-264.
Friborg J Jr, Kong W, Hottiger MO, Nabel GJ. p53 inhibition by the LANA protein of KSHV protects against cell death. Nature. 1999;402: 889-894.
Radkov SA, Kellam P, Boshoff C. The latent nuclear antigen of Kaposi sarcoma-associated herpesvirus targets the retinoblastoma-E2F pathway and with the oncogene Hras transforms primary rat cells. Nat Med. 2000;6: 1121-1127.
Davis MA, Sturzl MA, Blasig C, et al. Expression of human herpesvirus 8-encoded cyclin D in Kaposi's sarcoma spindle cells. J Natl Cancer Inst. 1997;89: 1868-1874.
Low W, Harries M, Ye H, Du MQ, Boshoff C, Collins M. Internal ribosome entry site regulates translation of Kaposi's sarcoma-associated herpesvirus FLICE inhibitory protein. J Virol. 2001; 75: 2938-2945.
Li M, Lee H, Yoon DW, et al. Kaposi's sarcoma-associated herpesvirus encodes a functional cyclin. J Virol. 1997;71: 1984-1991.
Godden-Kent D, Talbot SJ, Boshoff C, et al. The cyclin encoded by Kaposi's sarcoma-associated herpesvirus stimulates cdk6 to phosphorylate the retinoblastoma protein and histone H1. J Virol. 1997;71: 4193-4198.
Ellis M, Chew YP, Fallis L, et al. Degradation of p27(Kip) cdk inhibitor triggered by Kaposi's sarcoma virus cyclin-cdk6 complex. EMBO J. 1999; 18: 644-653.
Belanger C, Gravel A, Tomoiu A, et al. Human herpesvirus 8 viral FLICE-inhibitory protein inhibits Fas-mediated apoptosis through binding and prevention of procaspase-8 maturation. J Hum Virol. 2001;4: 62-73.
Field N, Low W, Daniels M, et al. KSHV vFLIP binds to IKK-gamma to activate IKK. J Cell Sci. 2003;116: 3721-3728.
Liu L, Eby MT, Rathore N, Sinha SK, Kumar A, Chaudhary PM. The human herpes virus 8-encoded viral FLICE inhibitory protein physically associates with and persistently activates the Ikappa B kinase complex. J Biol Chem. 2002; 277: 13745-13751.
Lukac DM, Kirshner JR, Ganem D. Transcriptional activation by the product of open reading frame 50 of Kaposi's sarcoma-associated herpesvirus is required for lytic viral reactivation in B cells. J Virol. 1999;73: 9348-9361.
Lukac DM, Renne R, Kirshner JR, Ganem D. Reactivation of Kaposi's sarcoma-associated herpesvirus infection from latency by expression of the ORF 50 transactivator, a homolog of the EBV R protein. Virology. 1998;252: 304-312.
Wu FY, Tang QQ, Chen H, et al. Lytic replication-associated protein (RAP) encoded by Kaposi sarcoma-associated herpesvirus causes p21CIP-1-mediated G1 cell cycle arrest through CCAAT/enhancer-binding protein-alpha. Proc Natl Acad Sci U S A. 2002;99: 10683-10688.
Glaunsinger B, Ganem D. Highly selective escape from KSHV-mediated host mRNA shutoff and its implications for viral pathogenesis. J Exp Med. 2004;200: 391-398.
Glaunsinger B, Ganem D. Lytic KSHV infection inhibits host gene expression by accelerating global mRNA turnover. Mol Cell. 2004;13: 713-723.
Gradoville L, Gerlach J, Grogan E, et al. Kaposi's sarcoma-associated herpesvirus open reading frame 50/Rta protein activates the entire viral lytic cycle in the HH-B2 primary effusion lymphoma cell line. J Virol. 2000;74: 6207-6212.
Wu FY, Ahn JH, Alcendor DJ, et al. Origin-independent assembly of Kaposi's sarcoma-associated herpesvirus DNA replication compartments in transient cotransfection assays and association with the ORF-K8 protein and cellular PML. J Virol. 2001;75: 1487-1506.
AuCoin DP, Colletti KS, Cei SA, Papouskova I, Tarrant M, Pari GS. Amplification of the Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 lytic origin of DNA replication is dependent upon a cis-acting AT-rich region and an ORF50 response element and the trans-acting factors ORF50 (K-Rta) and K8 (K-bZIP). Virology. 2004; 318: 542-555.
Kedes DH, Ganem D. Sensitivity of Kaposi's sarcoma-associated herpesvirus replication to antiviral drugs: implications for potential therapy. J Clin Invest. 1997;99: 2082-2086.
Tomicic MT, Thust R, Kaina B. Ganciclovir-induced apoptosis in HSV-1 thymidine kinase expressing cells: critical role of DNA breaks, Bcl-2 decline and caspase-9 activation. Oncogene. 2002;21: 2141-2153.
Cannon JS, Hamzeh F, Moore S, Nicholas J, Ambinder RF. Human herpesvirus 8-encoded thymidine kinase and phosphotransferase homologues confer sensitivity to ganciclovir. J Virol. 1999;73: 4786-4793.
Gustafson EA, Schinazi RF, Fingeroth JD. Human herpesvirus 8 open reading frame 21 is a thymidine and thymidylate kinase of narrow substrate specificity that efficiently phosphorylates zidovudine but not ganciclovir. J Virol. 2000;74: 684-692.
Lietman PS. Clinical pharmacology: foscarnet. Am J Med. 1992;92: 8S-11S.
Loscher W. Valproate: a reappraisal of its pharmacodynamic properties and mechanisms of action. Prog NeuroBiol. 1999;58: 31-59.
Bowden CL. New concepts in mood stabilization: evidence for the effectiveness of valproate and lamotrigine. Neuropsychopharmacology. 1998; 19: 194-199.
Shaw RN, Arbiser JL, Offermann MK. Valproic acid induces human herpesvirus 8 lytic gene expression in BCBL-1 cells. AIDS. 2000;14: 899-902.
Renne R, Zhong W, Herndier B, et al. Lytic growth of Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8) in culture. Nat Med. 1996;2: 342-346.
Inoue N, Winter J, Lal RB, Offermann MK, Koyano S. Characterization of entry mechanisms of human herpesvirus 8 by using an Rta-dependent reporter cell line. J Virol. 2003;77: 8147-8152.
Selden RF. Analysis of RNA by northern hybridization. In: Ausubel FM, Brent R, Kingston RE, et al, eds. Current Protocols in Molecular Biology. New York: John Wiley and Sons; 1987: 4.9.1-4.9.8.
Yu Y, Black JB, Goldsmith CS, Browning PJ, Bhalla K, Offermann MK. Induction of human herpesvirus-8 DNA replication and transcription by butyrate and TPA in BCBL-1 cells. J Gen Virol. 1999;80: 83-90.
Harcourt JL, Offermann MK. Interferon-alpha synergistically enhances induction of interleukin-6 by double stranded RNA in HeLa cells. Eur J BioChem. 2000;267: 2768-2777.
Krug LT, Pozharskaya VP, Yu Y, Inoue N, Offermann MK. Inhibition of infection and replication of human herpesvirus 8 in microvascular endothelial cells by alpha interferon and phosphonoformic acid. J Virol. 2004;78: 8359-8371.
Pozharskaya VP, Weakland LL, Zimring JC, et al. The short duration of elevated vIRF-1 expression during lytic replication of human herpesvirus 8 limits its ability to block antiviral responses induced by alpha interferon in BCBL-1 cells. J Virol. 2004;78: 6621-6635.
Chan SR, Chandran B. Characterization of human herpesvirus 8 ORF59 protein (PF-8) and mapping of the processivity and viral DNA polymerase-interacting domains. J Virol. 2000;74: 10920-10929.
Cannon JS, Ciufo D, Hawkins AL, et al. A new primary effusion lymphoma-derived cell line yields a highly infectious Kaposi's sarcoma herpesvirus-containing supernatant. J Virol. 2000;74: 10187-10193.
Alcami A, Koszinowski UH. Viral mechanisms of immune evasion. Trends MicroBiol. 2000;8: 410-418.
Balachandran S, Roberts PC, Brown LE, et al. Essential role for the dsRNA-dependent protein kinase PKR in innate immunity to viral infection. Immunity. 2000;13: 129-141.
Chawla-Sarkar M, Lindner DJ, Liu YF, et al. Apoptosis and interferons: role of interferon-stimulated genes as mediators of apoptosis. Apoptosis. 2003;8: 237-249.
Takaoka A, Hayakawa S, Yanai H, et al. Integration of interferon-alpha/beta signalling to p53 responses in tumour suppression and antiviral defence. Nature. 2003;424: 516-523.
Burysek L, Yeow WS, Lubyova B, et al. Functional analysis of human herpesvirus 8-encoded viral interferon regulatory factor 1 and its association with cellular interferon regulatory factors and p300. J Virol. 1999;73: 7334-7342.
Djerbi M, Screpanti V, Catrina AI, Bogen B, Biberfeld P, Grandien A. The inhibitor of death receptor signaling, FLICE-inhibitory protein defines a new class of tumor progression factors. J Exp Med. 1999;190: 1025-1032.
Park J, Seo T, Hwang S, Lee D, Gwack Y, Choe J. The K-bZIP protein from Kaposi's sarcoma-associated herpesvirus interacts with p53 and represses its transcriptional activity. J Virol. 2000; 74: 11977-11982.
Nakamura H, Li M, Zarycki J, Jung JU. Inhibition of p53 tumor suppressor by viral interferon regulatory factor. J Virol. 2001;75: 7572-7582.
Sarid R, Sato T, Bohenzky RA, Russo JJ, Chang Y. Kaposi's sarcoma-associated herpesvirus encodes a functional bcl-2 homologue. Nat Med. 1997;3: 293-298.
Pozharskaya VP, Weakland LL, Offermann MK. Inhibition of infectious human herpesvirus 8 production by gamma interferon and alpha interferon in BCBL-1 cells. J Gen Virol. 2004;85: 2779-2787.
Sarid R, Flore O, Bohenzky R, Chang Y, Moore P. Transcription mapping of the Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8) genome in a body-cavity-based lymphoma cell line (BC-1). J Virol. 1998;72: 1005-1012.
Seo T, Park J, Lee D, Hwang SG, Choe J. Viral interferon regulatory factor 1 of Kaposi's sarcoma-associated herpesvirus binds to p53 and represses p53-dependent transcription and apoptosis. J Virol. 2001;75: 6193-6198.
Cannon MJ, Dollard SC, Black JB, et al. Risk factors for Kaposi's sarcoma in men seropositive for both human herpesvirus 8 and human immunodeficiency virus. AIDS. 2003;17: 215-222.
Quinlivan EB, Zhang C, Stewart PW, Komoltri C, Davis MG, Wehbie RS. Elevated virus loads of Kaposi's sarcoma-associated human herpesvirus 8 predict Kaposi's sarcoma disease progression, but elevated levels of human immunodeficiency virus type 1 do not. J Infect Dis. 2002;185: 1736-1744.
Blaheta RA, Cinatl J Jr. Anti-tumor mechanisms of valproate: a novel role for an old drug. Med Res Rev. 2002;22: 492-511.
De Sarno P, Li X, Jope RS. Regulation of Akt and glycogen synthase kinase-3 beta phosphorylation by sodium valproate and lithium. Neuropharmacology. 2002;43: 1158-1164.
Gurvich N, Tsygankova OM, Meinkoth JL, Klein PS. Histone deacetylase is a target of valproic acid-mediated cellular differentiation. Cancer Res. 2004;64: 1079-1086.
Sawa H, Murakami H, Ohshima Y, et al. Histone deacetylase inhibitors such as sodium butyrate and trichostatin A induce apoptosis through an increase of the bcl-2-related protein Bad. Brain Tumor Pathol. 2001;18: 109-114.
Phillips A, Bullock T, Plant N. Sodium valproate induces apoptosis in the rat hepatoma cell line, FaO. Toxicology. 2003;192: 219-227.
Thomas GL, Henley A, Rowland TC, Sahai A, Griffin M, Birckbichler PJ. Enhanced apoptosis in transformed human lung fibroblasts after exposure to sodium butyrate. In Vitro Cell Dev Biol Anim. 1996;32: 505-513.
Alrabiah FA, Sacks SL. New antiherpesvirus agents: their targets and therapeutic potential. Drugs. 1996;52: 17-32.
Chrisp P, Clissold SP. Foscarnet: a review of its antiviral activity, pharmacokinetic properties and therapeutic use in immunocompromised patients with cytomegalovirus retinitis. Drugs. 1991;41: 104-129.
Dwyer DE, Kesson AM. Advances in antiviral therapy. Curr Opin Pediatr. 1997;9: 24-30.
Noormohamed FH, Youle MS, Higgs CJ, Martin-Munley S, Gazzard BG, Lant AF. Pharmacokinetics and absolute bioavailability of oral foscarnet in human immunodeficiency virus-seropositive patients. Antimicrob Agents Chemother. 1998;42: 293-297.
Piketty C, Bardin C, Gilquin J, Mahe V, Kazatchkine MD, Chast F. Low plasma concentrations achieved with conventional schedules of administration of ganciclovir in patients with AIDS. J Infect Dis. 1996;174: 188-190.(Carmen M. Klass, Laurie T)
Abstract
Primary effusion lymphoma (PEL) is a B-cell lymphoma in which human herpesvirus-8 (HHV-8) is found within all tumor cells and represents a target for selectively destroying tumor cells. HHV-8 is latent in most PEL cells and, hence, resistant to antiviral agents that inhibit lytic replication. We demonstrate that PEL cell lines containing HHV-8 without and with coinfection with Epstein-Barr virus responded to the antiseizure medication valproate with entry into the lytic cascade and production of infectious virus. Minimal cell death occurred when noninfected BL-41 cells were incubated with valproate, whereas apoptosis occurred in response to valproate in PELs that supported lytic replication of HHV-8. The anti-viral agents ganciclovir and phosphonoformic acid (PFA) blocked valproate-induced production of infectious virus without blocking entry into the lytic cascade, and apoptosis occurred at levels that were as high as when virus production was not blocked. Ganciclovir and PFA also prevented most valproate-induced expression of the late lytic viral transcript open reading frame 26 (ORF-26), but they did not block the induction of either viral interleukin-6 (vIL-6) or viral G protein-coupled receptor (vGPCR). These studies provide evidence that incubation of PELs with valproate in the presence of ganciclovir or PFA can selectively target tumor cells for apoptosis without increasing viral load.
Introduction
Human herpesvirus 8 (HHV-8; also known as Kaposi sarcoma herpesvirus or KSHV) is a large double-stranded DNA virus of the gamma herpesvirus family that is involved in the pathogenesis of both Kaposi sarcoma (KS) and primary effusion lymphoma (PEL).1,2 B lymphocytes serve as a reservoir for HHV-8, with viral infection persisting throughout the lifetime of the host.3-5 HHV-8-infected B lymphocytes can undergo malignant transformation, resulting in PELs.6-9 These rare B-cell lymphomas present as effusions without major lymph node or solid organ involvement.7,9 PEL cells are universally infected with HHV-8, and they are often coinfected with Epstein-Barr virus (EBV).10,11 They also contain multiple chromosomal abnormalities.11,12
The ability of HHV-8 to enter a latent state plays a key role in the development of HHV-8-associated tumors. During latency, the few viral proteins that are expressed help replicate the viral genome during cellular replication and ensure the survival of the infected population of cells.2,13 The disruption of important regulatory pathways that occurs during latency makes cells more susceptible to acquiring additional genetic or epigenetic changes that promote tumor development. All latently infected cells express the latency-associated nuclear antigen (LANA), a protein that is required for the replication of the viral episome and tethers it to cellular chromosomes during cell division.14-16 This ensures that the viral episome is maintained during cellular division so that the HHV-8 undergoes clonal expansion as latently infected cells replicate. LANA also disrupts the function of the tumor suppressor proteins p53 and Rb.17,18 Latently infected cells also express viral cyclin (v-cyclin) and viral Fas-associated death domain (FADD)-like interleukin-1-converting enzyme inhibitory protein (v-FLIP).19,20 The expression of v-cyclin contributes to unregulated proliferation of cells by activating cyclin dependent kinase 4 (cdk4) and cdk6, and it is resistant to inhibition by p21 and p16, unlike its cellular counterpart cyclin D.21-23 The v-FLIP protein inhibits apoptosis by activating the transcription factor nuclear factor-B (NF-B) and by preventing the activation of caspase 8.24-26 Together, the few viral genes that are expressed in latently infected cells enhance cell proliferation and reduce cell death.
The presence of HHV-8 in all PEL and KS cells3 provides a target for selective destruction of tumor cells without harming uninfected normal cells. HHV-8 is latent in most PEL cells but has the potential to switch to lytic replication.27,28 Lytic replication involves a complex cascade of viral gene expression to produce proteins required for replicating viral DNA and packaging it into infectious virions. Viral gene products expressed during lytic replication inhibit cellular gene expression and cellular replication, thereby conserving resources for viral production.29-31 Viral DNA polymerase is exclusively expressed during the lytic cascade and is required for lytic replication of viral DNA and expression of late lytic viral gene products.32-34 At appropriate concentrations, both ganciclovir and phosphonoformic acid (PFA, clinically known as foscarnet) can inhibit viral DNA polymerase, thereby preventing production of infectious virus.35 Ganciclovir is an acyclic nucleoside that undergoes phosphorylation by viral enzymes expressed during the lytic cascade. Phosphorylated ganciclovir inhibits viral DNA polymerase and can also be incorporated into cellular and viral DNA, leading to premature chain termination,36 whereas PFA is inhibitory to viral DNA polymerase without modification.37-39
In this study, we explored the consequences of combining viral DNA polymerase inhibitors with valproate (2-propylpentanoate). Valproate is clinically used to control partial and generalized epileptic seizures and neuropathic pain and to stabilize mood,40,41 and it is structurally and functionally similar to butyrate in its ability to induce lytic replication of HHV-8.42 We demonstrate that valproate inhibited proliferation and induced apoptosis of BCBL-1 and JSC-1 cells, PEL cell lines that are infected with HHV-8 in the absence and presence of coinfection with EBV, respectively.43 In contrast, valproate was nontoxic to a noninfected Burkitt lymphoma B-cell line. The valproate-induced production of infectious HHV-8 from BCBL-1 and JSC-1 cells was blocked by either ganciclovir or PFA, whereas apoptosis continued to occur. These studies indicate that the combined use of valproate and viral DNA polymerase inhibitors can selectively target HHV-8-infected cells for apoptotic death without increasing the viral load.
Materials and methods
Cell culture
BCBL-1 cells (HHV-8-positive, EBV-negative) and BL-41 cell line (HHV-8-negative, EBV-negative) were obtained from the National Institutes of Health AIDS Research and Reference Program (Rockville, MD). JSC-1 cells were kindly provided by Dr Richard Ambinder (Johns Hopkins University, Baltimore, MD). All cells were maintained in RPMI 1640 medium supplemented with 10% fetal calf serum, 2 mM L-glutamine, 100 U penicillin, and 10 U streptomycin. A reporter cell line for quantification analysis of infectious HHV-8, T1H6,44 was maintained in Dulbecco modification of Eagle medium (Cellgro, Herndon, VA) supplemented with 10% fetal bovine serum, 2 mM L-glutamine, 200 U/mL penicillin, 10 U/mL streptomycin, and 50 μg/mL hygromycin B (Invitrogen, Carlsbad, CA) and split 1:10 every 3 to 4 days. Valproate (2-propylpentanoic acid), butyrate, ganciclovir, and phosphonoformic acid were purchased from Sigma-Aldrich (St Louis, MO).
Northern blot analysis
Total cellular RNA was isolated using Trizol (GibcoBRL, Grand Island, NY) and was size fractionated on a 1% agarose/formaldehyde gel.45 RNA was transferred to nitrocellulose and covalently linked by ultraviolet irradiation using a Stratalinker (Stratagene, La Jolla, CA) and by baking in vacuo for 2 hours at 80°C. DNA probes for viral interleukin 6 (vIL-6),46 viral G protein-coupled receptor (vGPCR), open reading frame 26 (ORF-26), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH)47 were radiolabeled using an oligolabeling kit (Stratagene) with 32P deoxycytidine triphosphate (dCTP) according to the manufacturer's recommendations. Hybridizations were performed at 42°C in 20 x standard saline citrate (SSC), 10% sodium dodecyl sulfate (SDS), 50 x Denhart, 100 μg/mL denatured salmon sperm DNA, 50% formamide, 10% dextran sulfate, and 100 ng 32P-dCTP-labeled DNA at a specific activity of 1 x 108 cpm/μg. Nitrocellulose was washed with a final stringency of 0.2 x SSC in 0.1% SDS at 55°C. Blots were serially probed for the genes indicated, and the nitrocellulose was stripped using boiling water prior to rehybridization with other probes. Autoradiography was performed with an intensifying screen at –80°C.
Immunofluorescence
Cytospin preparations from BCBL-1 and JSC-1 cells were air-dried and fixed in ice-cold acetone. Slides were rehydrated with phosphate-buffered saline (PBS) for 10 minutes. The terminal deoxynucleotidyl transferase (TdT) nick end labeling (TUNEL) assay was done according to the manufacturer's recommendation (DeadEnd Fluorometric TUNEL System; Promega, Madison, WI). After the terminal deoxynucleotidyl transferase (TdT) enzyme incubation and the termination of the reaction with 2 x SSC, slides were washed 3 times with PBS and subjected to immunohistochemical staining for DNA polymerase processivity factor (PPF) using a mouse monoclonal antibody to PPF, the product of ORF-59 (anti-ORF-59, 1:100; Advanced Biotechnologies, Columbia, MD). Slides were blocked with goat serum for 10 minutes at 37°C prior to overnight incubation at 4°C in a wet chamber with anti-ORF-59 in 5% goat serum. Slides were then washed 3 times and incubated for 45 minutes at 37°C with goat anti-mouse Alexa Fluor 567 (Molecular Probes, Eugene, OR). Slides were washed 3 times with PBS and then mounted with antifading agent. Imaging was performed using a Nikon Eclipse E-800 microscope equipped with an oil immersion 100x/1.3 objective lens and an Optronics MagnaFire S99800 digital camera. The emission patterns of the 2 fluorescences were collected separately. Identical exposure times were used for data acquisition from each slide for the individual fluorescent probes.
Assessment of cell viability and apoptosis
Cell viability was determined by trypan blue exclusion and direct counting with a hemacytometer. Apoptosis was determined by using the DeadEnd Fluorometric TUNEL System (Promega) according to the manufacturer's recommendation. Cells (2 x 106) were fixed in ice-cold 1% formaldehyde, washed with PBS, and permeabilized with 70% ethanol for 24 hours at -20°C. The fragmented DNA of apoptotic cells was identified by catalytically incorporating fluorescein-12-dUTP at 3'-OH DNA ends, using the enzyme TdT in TdT incubation buffer. As a control, cells were treated with incubation buffer that did not contain TdT enzyme. Cells were analyzed using a FACScan flow cytometer (Becton Dickinson, San Jose, CA).
Assay for infectious HHV-8 production using the T1H6 cell line
The T1H6 reporter cell line contains the lacZ gene under a control of the PAN promoter and responds to infection with HHV-8 in a sensitive and quantitative manner that accurately assesses the amount of infectious HHV-8 present.44,48,49 Briefly, 8 x 104 T1H6 cells/well were seeded in 48-well plates in triplicate. The next day, 200 μL medium from PEL cells was assayed for infectious virus by filtering it through a 0.45-μm filter and then adding it to T1H6 cells in the presence of 8 μg/mL polybrene (Sigma, St Louis, MO). Plates with T1H6 cells were centrifuged at 400g for 30 minutes at room temperature and incubated at 37°C for 1.5 hours. The medium was changed, and cells were incubated for 2 days at 37°C. After 3 freeze-thaw cycles with 50 μL PBS, cell lysates were harvested, and their -galactosidase activities were measured by Luminescent -galactosidase assay (Clontech, Palo Alto, CA) using LUMIstar Galaxy luminometer (BMG LabTechnologies, Durham, NC). For the standard curve, dilution series of infectious virus were used as well as serial dilutions of the -galactosidase.
Results
Changes in cell number and production of infectious virus resulting from incubation with valproate
There is extensive clinical information on the safety and toxicity of valproate in patients treated for neurologic conditions. Plasma concentrations during chronic oral treatment typically range from 0.28 mM to 0.69 mM.40 We previously demonstrated that a concentration of valproate between 0.03 and 3 mM induced the expression of lytic cycle-associated HHV-8 genes.42 Here, we examined changes in cell proliferation, cell survival, and production of infectious virus using a concentration of valproate that is clinically encountered. When BCBL-1 cells were incubated with 0.6 mM valproate, there was an inhibition of the increase in cell number that occurred over time that was very similar to the inhibition that occurred using 0.6 mM butyrate (Figure 1A). Untreated cells showed a more than 7-fold increase in cell number over 3 days, and then cell numbers plateaued. When valproate was present, the plateau occurred much earlier, with a more than 50% reduction in total cell number compared with control cells. The TUNEL assay was used to assess the role of apoptosis in the changes in cell number. Incubation with valproate caused a time-dependent increase in the percentage of cells undergoing apoptosis, with 40% of cells being TUNEL-positive on day 2 and more than 70% by day 3 (Figure 1B). In contrast, approximately 10% of control cells were undergoing apoptosis, and this remained relatively constant over a 4-day period.
A number of steps need to be successfully completed in the lytic cascade of HHV-8 for infectious virus to be produced. We have previously reported that incubation with 3 mM butyrate induces apoptosis prior to completion of virus production, whereas apoptosis occurs at later time points that do not prevent the production of intact virions when the concentration of butyrate is reduced to 0.3 mM.46 We thus compared the amount of infectious virus that was present in the conditioned medium at various time points after incubation with either 0.6 mM valproate or 0.3 mM butyrate. The amount of extracellular infectious virus in conditioned medium was determined by using the T1H6 reporter cell line that contains an HHV-8 Rta-dependent promoter linked to a -galactosidase gene, and the expression of -galactosidase is directly proportional to the amount of infectious virus present.44,48,49 There was a low level of infectious virus detected in the conditioned medium from BCBL-1 cells 3 days following stimulation with either valproate or butyrate, whereas there was no detectable infectious virus in conditioned medium from control cells (Figure 1C). By day 4, the amount of infectious virus in the conditioned medium showed a sharp increase in response to both valproate and butyrate, with levels peaking by day 5. There was no further increase in the amount of infectious virus in the medium during longer incubations (data not shown). When BCBL-1 cells were incubated with 0.6 mM valproate, more infectious virus was produced than when cells were incubated with 0.3 mM butyrate (Figure 1C). Thus, the apoptosis that resulted from incubation with valproate did not prevent the release of infectious virus, suggesting that apoptosis occurred after the completion of virus production in many of the cells.
Sensitivity of HHV-8-infected and uninfected B-cell lines to valproate and antivirals
A nonvirally infected Burkitt lymphoma B-cell line (BL41) was compared with HHV-8-infected BCBL-1 cells to determine whether the apoptosis that resulted from valproate was due to cellular changes independent of HHV-8. For all conditions examined, incubation with valproate did not significantly reduce the number of BL41 cells (Figure 2A), whereas there was more than a 50% reduction in cell number when BCBL-1 cells were incubated with valproate (Figure 2B). Ganciclovir at 2 and 20 μM was well tolerated by both cell types, whereas 200 μM ganciclovir was toxic to both cell types, causing a 70% reduction in the number of BL41 cells and a 50% reduction in the number of BCBL-1 cells (Figure 2A-B). The cell death resulting from ganciclovir at 200 μM was not related to the antiviral effects of ganciclovir since the BL41 cells were not virally infected. PFA at either 100 or 750 μM was well tolerated by BL41 cells, but there was a 25% reduction in BCBL-1 cell number resulting from incubation with 750 μM PFA. The reduction occurred independent of valproate-induced entry into the lytic cascade.
Effect of ganciclovir and PFA on valproate induced mRNA expression
Concentrations of ganciclovir and PFA that are effective at blocking viral DNA polymerase should inhibit the expression of late lytic viral mRNAs, a group of viral transcripts that are dependent on lytic viral DNA replication for expression.1,5 Northern blot analysis demonstrated that incubation with valproate for 4 days induced high levels of expression of the late lytic transcript ORF-26 (Figure 3). Both ganciclovir and PFA caused a concentration-dependent reduction in ORF-26 expression. Incubation with 750 μM PFA blocked all valproate-induced expression of ORF-26, whereas expression of ORF-26 was reduced but not fully blocked by ganciclovir at 2 to 20 μM or PFA at 100 μM. Valproate also induced high levels of expression of vIL-6 and vGPCR, but neither ganciclovir nor PFA prevented their induction. This was expected since viral transcripts expressed early in the lytic cascade are not dependent on viral DNA polymerase for expression. The slight reduction in the amount of vIL-6 and vGPCR that occurred when valproate-stimulated cells were incubated with PFA of 750 μM was accompanied by less GAPDH mRNA, suggesting that it was due to loading differences in mRNA or the toxic effects that were noted at this concentration. The levels of the cellular mRNA GAPDH decreased when cells were incubated with valproate both in the absence and presence of ganciclovir and PFA, consistent with the known inhibition of cellular gene transcription that occurs during lytic replication.30,31
Inhibition of valproate-induced production of HHV-8 by ganciclovir and PFA
Inhibition of ORF-26 expression provided evidence that PFA at 750 μM was the most effective inhibitor of valproate-induced production of infectious virus, with 20 μM ganciclovir nearly as effective. We explored the relative efficacy of the agents in more detail by using the T1H6 reporter cell line to assess the amount of infectious virus released by BCBL-1 cells since viral particles can often be defective and noninfectious. When BCBL-1 cells were incubated with valproate for 5 days, there was a large increase in the amount of infectious virus in the conditioned medium, leading to a large increase in reporter cell activity (Figure 4). When either ganciclovir (2 or 20 μM) or PFA (100 or 750 μM) were present during incubation with valproate, the increased production of infectious virus was almost completely blocked. Thus, the low level of late gene expression that was observed when valproate-stimulated BCBL-1 cells were incubated with ganciclovir at 2 to 20 μm or PFA at 100 μM was accompanied by minimal release of infectious virus.
Valproate-induced apoptosis in BCBL-1 cells incubated with ganciclovir and PFA
Incubation of BCBL-1 cells with valproate for 3 days increased the percentage of cells undergoing apoptosis by approximately 4-fold (Figure 5). When ganciclovir or PFA was present to inhibit viral DNA replication and late lytic gene expression, there was no reduction in the amount of apoptosis that occurred (Figure 5A-B), indicating that valproate-induced apoptosis was not dependent on viral DNA replication or on the expression of late viral gene products. Incubation with valproate for 4 days induced nearly the entire population of BCBL-1 cells to enter the lytic phase of viral replication, reflected by the expression of DNA polymerase processivity factor (PPF), a protein encoded by ORF-59 that is exclusively expressed during the lytic cascade50 (Figure 5C). Most cells that were expressing PPF were undergoing apoptosis at this time point, and the apoptosis was not blocked by ganciclovir (Figure 5C) or PFA (data not shown).
While BCBL-1 cells are infected with HHV-8 and not with EBV, most PELs, including JSC-1 cells, are coinfected with both HHV-8 and EBV.51 We examined the response of JSC-1 cells to valproate in the absence and presence of antivirals to determine whether coinfected PELs were also susceptible to valproate-induced lytic replication and apoptosis. There was a time-dependent increase in cell number when JSC-1 cells were incubated under control conditions, and the increase in cell number was reduced by incubation with valproate at either 0.6 or 1.2 mM (Figure 6A). Incubation with valproate induced the accumulation of infectious virus in the medium, with more virus produced when cells were incubated with 1.2 mM valproate than with 0.6 mM valproate (Figure 6B). Both ganciclovir and PFA effectively blocked the valproate-induced production of infectious virus. JSC-1 cells that were incubated with valproate underwent apoptosis, and inhibition of virus production did not prevent valproate-induced apoptosis (Figure 6C). Immunofluorescent analysis demonstrated that the majority of JSC-1 cells incubated with valproate expressed PPF, and the PPF-positive cells became TUNEL positive, similar to the BCBL-1 cells shown in Figure 5C (data not shown). Thus, the HHV-8 in PELs responded to valproate with entry into the lytic cascade and apoptosis irrespective of whether EBV was present or absent.
Discussion
These studies demonstrate that incubation with valproate induced HHV-8 in PEL cells to enter the lytic cascade, leading to production of infectious virus and the death of most cells by apoptosis. Minimal cell death occurred when noninfected BL-41 cells were incubated with valproate, providing evidence that the apoptosis that occurred in PEL cells was more closely linked to the lytic replication of HHV-8 than to cellular changes induced by valproate. The induction of lytic replication of HHV-8 that occurred with valproate was seen with PELs both with and without coinfection with EBV. Both ganciclovir and PFA blocked valproate-induced production of HHV-8 without blocking entry into the lytic cascade, and apoptosis continued to occur at levels that were as high as when virus production was not blocked. This indicates that the apoptosis was not dependent on replication of viral DNA or on completion of the lytic cascade.
Apoptosis represents an important mechanism used by the host to eliminate virally infected cells.52-55 There are viral gene products expressed during both latent and lytic replication that inhibit apoptosis,17,20,56-60 yet these did not prevent apoptosis in cells supporting lytic replication of HHV-8. Immunofluorescent studies examining PPF demonstrated that a few cells that spontaneously entered the lytic cascade were TUNEL positive, whereas surrounding cells that did not express PPF were TUNEL negative. This indicates that apoptosis occurred in cells that entered the lytic cascade independent of incubation with valproate. Similarly, lytic replication induced by either 12-O-tetradecanoylphorbol-13-acetate (TPA) or butyrate leads to apoptosis of BCBL-1 cells.46,49,61 More transcripts and proteins are expressed at high levels during the lytic cascade than during latency, and this increases the likelihood of detection by cellular defenses.46,49,61,62 Apoptosis occurred when viral late gene expression was blocked, indicating that changes occurring early in the lytic cascade were sufficient to induce apoptosis despite expression of viral proteins with antiapoptotic activity. The transient expression of some antiapoptotic proteins limits their ability to suppress apoptosis. For example, overexpression of viral interferon (IFN) regulatory factor 1 (vIRF-1) can suppress apoptosis,56,63 but vIRF-1 is expressed relatively early in the lytic cascade, and its expression is transient because of a short half-life, thereby limiting its ability to block apoptosis.49 The increase in viral DNA that occurs during lytic replication is not required for the apoptotic response since inhibition of viral DNA replication did not reduce the level of apoptosis that occurred. This suggests that viral transcripts and/or proteins expressed during the lytic cascade were responsible for triggering apoptosis.
The concentration of valproate that we used to induce lytic replication of HHV-8 was in the range that is present in the plasma of patients treated with valproate for neurologic diseases.40 This indicates that patients taking valproate who are latently infected with HHV-8 are at risk for lytic reactivation of HHV-8 and production of infectious virus unless virus production is blocked. This could increase the likelihood of developing HHV-8-associated diseases such as KS since the development of new KS lesions is more likely to occur when circulating virus is detected.64,65 Valproate and butyrate are very similar in structure and display nearly identical dose-response curves for lytic gene induction.42 Both valproate and butyrate function as histone deacetylase inhibitors and affect the expression of both cellular and viral genes.66-69 BCBL-1 cells respond to high concentrations of butyrate and valproate with apoptosis prior to production of infectious virus, but this does not occur in response to TPA.46 This suggests that the apoptosis that results from valproate and butyrate has a cellular component that augments the apoptosis triggered by lytic replication, consistent with the ability of these agents to induce apoptosis in some nonvirally infected cells.66,67,69-71
The apoptosis that occurs as a consequence of valproate-induced lytic reactivation represents an opportunity to selectively kill virally infected cells while blocking production of infectious virus. PFA directly inhibits the viral DNA polymerase by binding to the pyrophosphate-binding site at concentrations that do not affect the cellular polymerase,72-74 whereas ganciclovir must first undergo phosphorylation by either HHV-8 viral thymidine kinase (ORF-21) or viral phosphotransferase (ORF-36), proteins that are expressed exclusively during the lytic cascade.37 The phosphorylated ganciclovir can then undergo additional phosphorylation by cellular enzymes, thereby creating an acyclic nucleic acid that can be incorporated into either viral or cellular DNA. PFA was as effective at preventing viral production as ganciclovir, and apoptosis continued to occur. This indicates that incorporation of acyclic nucleotides into DNA is not required for induction of apoptosis, suggesting that the apoptosis occurs in large part as a cellular response to viral products expressed during the lytic cascade.
The tumor cells for both PEL and KS harbor HHV-8 that is primarily latent. Pharmacokinetic studies of valproate, PFA, and ganciclovir demonstrate that concentrations that were effective in this study can be safely achieved in patients.40,75,76 This suggests that combined treatment with valproate and antiviral agents could selectively target tumors that are infected with HHV-8 for destruction without killing noninfected cells. Either PFA or ganciclovir should prevent valproate-induced production of HHV-8 without preventing apoptosis, and this should limit any long-term problems associated with virus dissemination or paracrine responses to viral proteins such as vIL-6 that are expressed early in the lytic cascade.
Footnotes
Prepublished online as Blood First Edition Paper, February 1, 2005; DOI 10.1182/blood-2004-09-3569.
Supported by the US Public Health Service (grant RO-1 CA 79402).
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
References
Moore PS, Chang Y. Kaposi's sarcoma-associated herpesvirus. In: Fields B, Knipe D, Howley P, eds. Field's Virology. Vol 2. 4th ed. Philadelphia: Lippencott-Raven Publishers; 2001: 2803-2833.
Viejo-Borbolla A, Ottinger M, Schulz TF. Human herpesvirus 8: biology and role in the pathogenesis of Kaposi's sarcoma and other AIDS-related malignancies. Curr Infect Dis Rep. 2003;5: 169-175.
Dupin N, Fisher C, Kellam P, et al. Distribution of human herpesvirus-8 latently infected cells in Kaposi's sarcoma, multicentric Castleman's disease, and primary effusion lymphoma. Proc Natl Acad Sci U S A. 1999;96: 4546-4551.
Matsushima AY, Strauchen JA, Lee G, et al. Post-transplantation plasmacytic proliferations related to Kaposi's sarcoma-associated herpesvirus. Am J Surg Pathol. 1999;23: 1393-1400.
Roizman B, Philip PE. The family herpesviridae: a brief introduction. In: Fields B, Knipe D, Howley P, eds. Field's Virology. Vol 2. 4th ed. Philadelphia, PA: Lippencott-Raven; 2001: 2381-2397.
Mesri EA, Cesarman E, Arvanitakis L, et al. Human herpesvirus-8/Kaposi's sarcoma-associated herpesvirus is a new transmissible virus that infects B cells. J Exp Med. 1996;183: 2385-2390.
Cesarman E, Knowles DM. The role of Kaposi's sarcoma-associated herpesvirus (KSHV/HHV-8) in lymphoproliferative diseases. Semin Cancer Biol. 1999;9: 165-174.
Carbone A, Cilia AM, Gloghini A, et al. Establishment and characterization of EBV-positive and EBV-negative primary effusion lymphoma cell lines harbouring human herpesvirus type-8. Br J Haematol. 1998;102: 1081-1089.
Cesarman E, Nador RG, Aozasa K, Delsol G, Said JW, Knowles DM. Kaposi's sarcoma-associated herpesvirus in non-AIDS related lymphomas occurring in body cavities. Am J Pathol. 1996; 149: 53-57.
Callahan J, Pai S, Cotter M, Robertson ES. Distinct patterns of viral antigen expression in Epstein-Barr virus and Kaposi's sarcoma-associated herpesvirus coinfected body-cavity-based lymphoma cell lines: potential switches in latent gene expression due to coinfection. Virology. 1999; 262: 18-30.
Drexler HG, Uphoff CC, Gaidano G, Carbone A. Lymphoma cell lines: in vitro models for the study of HHV-8+ primary effusion lymphomas (body cavity-based lymphomas). Leukemia. 1998;12: 1507-1517.
Gaidano G, Capello D, Fassone L, et al. Molecular characterization of HHV-8 positive primary effusion lymphoma reveals pathogenetic and histogenetic features of the disease. J Clin Virol. 2000; 16: 215-224.
Collins CM, Medveczky PG. Genetic requirements for the episomal maintenance of oncogenic herpesvirus genomes. Adv Cancer Res. 2002;84: 155-174.
Kedes DH, Lagunoff M, Renne R, Ganem D. Identification of the gene encoding the major latency-associated nuclear antigen of the Kaposi's sarcoma-associated herpesvirus. J Clin Invest. 1997;100: 2606-2610.
Ballestas ME, Chatis PA, Kaye KM. Efficient persistence of extrachromosomal KSHV DNA mediated by latency-associated nuclear antigen. Science. 1999;284: 641-644.
Cotter MA II, Robertson ES. The latency-associated nuclear antigen tethers the Kaposi's sarcoma-associated herpesvirus genome to host chromosomes in body cavity-based lymphoma cells. Virology. 1999;264: 254-264.
Friborg J Jr, Kong W, Hottiger MO, Nabel GJ. p53 inhibition by the LANA protein of KSHV protects against cell death. Nature. 1999;402: 889-894.
Radkov SA, Kellam P, Boshoff C. The latent nuclear antigen of Kaposi sarcoma-associated herpesvirus targets the retinoblastoma-E2F pathway and with the oncogene Hras transforms primary rat cells. Nat Med. 2000;6: 1121-1127.
Davis MA, Sturzl MA, Blasig C, et al. Expression of human herpesvirus 8-encoded cyclin D in Kaposi's sarcoma spindle cells. J Natl Cancer Inst. 1997;89: 1868-1874.
Low W, Harries M, Ye H, Du MQ, Boshoff C, Collins M. Internal ribosome entry site regulates translation of Kaposi's sarcoma-associated herpesvirus FLICE inhibitory protein. J Virol. 2001; 75: 2938-2945.
Li M, Lee H, Yoon DW, et al. Kaposi's sarcoma-associated herpesvirus encodes a functional cyclin. J Virol. 1997;71: 1984-1991.
Godden-Kent D, Talbot SJ, Boshoff C, et al. The cyclin encoded by Kaposi's sarcoma-associated herpesvirus stimulates cdk6 to phosphorylate the retinoblastoma protein and histone H1. J Virol. 1997;71: 4193-4198.
Ellis M, Chew YP, Fallis L, et al. Degradation of p27(Kip) cdk inhibitor triggered by Kaposi's sarcoma virus cyclin-cdk6 complex. EMBO J. 1999; 18: 644-653.
Belanger C, Gravel A, Tomoiu A, et al. Human herpesvirus 8 viral FLICE-inhibitory protein inhibits Fas-mediated apoptosis through binding and prevention of procaspase-8 maturation. J Hum Virol. 2001;4: 62-73.
Field N, Low W, Daniels M, et al. KSHV vFLIP binds to IKK-gamma to activate IKK. J Cell Sci. 2003;116: 3721-3728.
Liu L, Eby MT, Rathore N, Sinha SK, Kumar A, Chaudhary PM. The human herpes virus 8-encoded viral FLICE inhibitory protein physically associates with and persistently activates the Ikappa B kinase complex. J Biol Chem. 2002; 277: 13745-13751.
Lukac DM, Kirshner JR, Ganem D. Transcriptional activation by the product of open reading frame 50 of Kaposi's sarcoma-associated herpesvirus is required for lytic viral reactivation in B cells. J Virol. 1999;73: 9348-9361.
Lukac DM, Renne R, Kirshner JR, Ganem D. Reactivation of Kaposi's sarcoma-associated herpesvirus infection from latency by expression of the ORF 50 transactivator, a homolog of the EBV R protein. Virology. 1998;252: 304-312.
Wu FY, Tang QQ, Chen H, et al. Lytic replication-associated protein (RAP) encoded by Kaposi sarcoma-associated herpesvirus causes p21CIP-1-mediated G1 cell cycle arrest through CCAAT/enhancer-binding protein-alpha. Proc Natl Acad Sci U S A. 2002;99: 10683-10688.
Glaunsinger B, Ganem D. Highly selective escape from KSHV-mediated host mRNA shutoff and its implications for viral pathogenesis. J Exp Med. 2004;200: 391-398.
Glaunsinger B, Ganem D. Lytic KSHV infection inhibits host gene expression by accelerating global mRNA turnover. Mol Cell. 2004;13: 713-723.
Gradoville L, Gerlach J, Grogan E, et al. Kaposi's sarcoma-associated herpesvirus open reading frame 50/Rta protein activates the entire viral lytic cycle in the HH-B2 primary effusion lymphoma cell line. J Virol. 2000;74: 6207-6212.
Wu FY, Ahn JH, Alcendor DJ, et al. Origin-independent assembly of Kaposi's sarcoma-associated herpesvirus DNA replication compartments in transient cotransfection assays and association with the ORF-K8 protein and cellular PML. J Virol. 2001;75: 1487-1506.
AuCoin DP, Colletti KS, Cei SA, Papouskova I, Tarrant M, Pari GS. Amplification of the Kaposi's sarcoma-associated herpesvirus/human herpesvirus 8 lytic origin of DNA replication is dependent upon a cis-acting AT-rich region and an ORF50 response element and the trans-acting factors ORF50 (K-Rta) and K8 (K-bZIP). Virology. 2004; 318: 542-555.
Kedes DH, Ganem D. Sensitivity of Kaposi's sarcoma-associated herpesvirus replication to antiviral drugs: implications for potential therapy. J Clin Invest. 1997;99: 2082-2086.
Tomicic MT, Thust R, Kaina B. Ganciclovir-induced apoptosis in HSV-1 thymidine kinase expressing cells: critical role of DNA breaks, Bcl-2 decline and caspase-9 activation. Oncogene. 2002;21: 2141-2153.
Cannon JS, Hamzeh F, Moore S, Nicholas J, Ambinder RF. Human herpesvirus 8-encoded thymidine kinase and phosphotransferase homologues confer sensitivity to ganciclovir. J Virol. 1999;73: 4786-4793.
Gustafson EA, Schinazi RF, Fingeroth JD. Human herpesvirus 8 open reading frame 21 is a thymidine and thymidylate kinase of narrow substrate specificity that efficiently phosphorylates zidovudine but not ganciclovir. J Virol. 2000;74: 684-692.
Lietman PS. Clinical pharmacology: foscarnet. Am J Med. 1992;92: 8S-11S.
Loscher W. Valproate: a reappraisal of its pharmacodynamic properties and mechanisms of action. Prog NeuroBiol. 1999;58: 31-59.
Bowden CL. New concepts in mood stabilization: evidence for the effectiveness of valproate and lamotrigine. Neuropsychopharmacology. 1998; 19: 194-199.
Shaw RN, Arbiser JL, Offermann MK. Valproic acid induces human herpesvirus 8 lytic gene expression in BCBL-1 cells. AIDS. 2000;14: 899-902.
Renne R, Zhong W, Herndier B, et al. Lytic growth of Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8) in culture. Nat Med. 1996;2: 342-346.
Inoue N, Winter J, Lal RB, Offermann MK, Koyano S. Characterization of entry mechanisms of human herpesvirus 8 by using an Rta-dependent reporter cell line. J Virol. 2003;77: 8147-8152.
Selden RF. Analysis of RNA by northern hybridization. In: Ausubel FM, Brent R, Kingston RE, et al, eds. Current Protocols in Molecular Biology. New York: John Wiley and Sons; 1987: 4.9.1-4.9.8.
Yu Y, Black JB, Goldsmith CS, Browning PJ, Bhalla K, Offermann MK. Induction of human herpesvirus-8 DNA replication and transcription by butyrate and TPA in BCBL-1 cells. J Gen Virol. 1999;80: 83-90.
Harcourt JL, Offermann MK. Interferon-alpha synergistically enhances induction of interleukin-6 by double stranded RNA in HeLa cells. Eur J BioChem. 2000;267: 2768-2777.
Krug LT, Pozharskaya VP, Yu Y, Inoue N, Offermann MK. Inhibition of infection and replication of human herpesvirus 8 in microvascular endothelial cells by alpha interferon and phosphonoformic acid. J Virol. 2004;78: 8359-8371.
Pozharskaya VP, Weakland LL, Zimring JC, et al. The short duration of elevated vIRF-1 expression during lytic replication of human herpesvirus 8 limits its ability to block antiviral responses induced by alpha interferon in BCBL-1 cells. J Virol. 2004;78: 6621-6635.
Chan SR, Chandran B. Characterization of human herpesvirus 8 ORF59 protein (PF-8) and mapping of the processivity and viral DNA polymerase-interacting domains. J Virol. 2000;74: 10920-10929.
Cannon JS, Ciufo D, Hawkins AL, et al. A new primary effusion lymphoma-derived cell line yields a highly infectious Kaposi's sarcoma herpesvirus-containing supernatant. J Virol. 2000;74: 10187-10193.
Alcami A, Koszinowski UH. Viral mechanisms of immune evasion. Trends MicroBiol. 2000;8: 410-418.
Balachandran S, Roberts PC, Brown LE, et al. Essential role for the dsRNA-dependent protein kinase PKR in innate immunity to viral infection. Immunity. 2000;13: 129-141.
Chawla-Sarkar M, Lindner DJ, Liu YF, et al. Apoptosis and interferons: role of interferon-stimulated genes as mediators of apoptosis. Apoptosis. 2003;8: 237-249.
Takaoka A, Hayakawa S, Yanai H, et al. Integration of interferon-alpha/beta signalling to p53 responses in tumour suppression and antiviral defence. Nature. 2003;424: 516-523.
Burysek L, Yeow WS, Lubyova B, et al. Functional analysis of human herpesvirus 8-encoded viral interferon regulatory factor 1 and its association with cellular interferon regulatory factors and p300. J Virol. 1999;73: 7334-7342.
Djerbi M, Screpanti V, Catrina AI, Bogen B, Biberfeld P, Grandien A. The inhibitor of death receptor signaling, FLICE-inhibitory protein defines a new class of tumor progression factors. J Exp Med. 1999;190: 1025-1032.
Park J, Seo T, Hwang S, Lee D, Gwack Y, Choe J. The K-bZIP protein from Kaposi's sarcoma-associated herpesvirus interacts with p53 and represses its transcriptional activity. J Virol. 2000; 74: 11977-11982.
Nakamura H, Li M, Zarycki J, Jung JU. Inhibition of p53 tumor suppressor by viral interferon regulatory factor. J Virol. 2001;75: 7572-7582.
Sarid R, Sato T, Bohenzky RA, Russo JJ, Chang Y. Kaposi's sarcoma-associated herpesvirus encodes a functional bcl-2 homologue. Nat Med. 1997;3: 293-298.
Pozharskaya VP, Weakland LL, Offermann MK. Inhibition of infectious human herpesvirus 8 production by gamma interferon and alpha interferon in BCBL-1 cells. J Gen Virol. 2004;85: 2779-2787.
Sarid R, Flore O, Bohenzky R, Chang Y, Moore P. Transcription mapping of the Kaposi's sarcoma-associated herpesvirus (human herpesvirus 8) genome in a body-cavity-based lymphoma cell line (BC-1). J Virol. 1998;72: 1005-1012.
Seo T, Park J, Lee D, Hwang SG, Choe J. Viral interferon regulatory factor 1 of Kaposi's sarcoma-associated herpesvirus binds to p53 and represses p53-dependent transcription and apoptosis. J Virol. 2001;75: 6193-6198.
Cannon MJ, Dollard SC, Black JB, et al. Risk factors for Kaposi's sarcoma in men seropositive for both human herpesvirus 8 and human immunodeficiency virus. AIDS. 2003;17: 215-222.
Quinlivan EB, Zhang C, Stewart PW, Komoltri C, Davis MG, Wehbie RS. Elevated virus loads of Kaposi's sarcoma-associated human herpesvirus 8 predict Kaposi's sarcoma disease progression, but elevated levels of human immunodeficiency virus type 1 do not. J Infect Dis. 2002;185: 1736-1744.
Blaheta RA, Cinatl J Jr. Anti-tumor mechanisms of valproate: a novel role for an old drug. Med Res Rev. 2002;22: 492-511.
De Sarno P, Li X, Jope RS. Regulation of Akt and glycogen synthase kinase-3 beta phosphorylation by sodium valproate and lithium. Neuropharmacology. 2002;43: 1158-1164.
Gurvich N, Tsygankova OM, Meinkoth JL, Klein PS. Histone deacetylase is a target of valproic acid-mediated cellular differentiation. Cancer Res. 2004;64: 1079-1086.
Sawa H, Murakami H, Ohshima Y, et al. Histone deacetylase inhibitors such as sodium butyrate and trichostatin A induce apoptosis through an increase of the bcl-2-related protein Bad. Brain Tumor Pathol. 2001;18: 109-114.
Phillips A, Bullock T, Plant N. Sodium valproate induces apoptosis in the rat hepatoma cell line, FaO. Toxicology. 2003;192: 219-227.
Thomas GL, Henley A, Rowland TC, Sahai A, Griffin M, Birckbichler PJ. Enhanced apoptosis in transformed human lung fibroblasts after exposure to sodium butyrate. In Vitro Cell Dev Biol Anim. 1996;32: 505-513.
Alrabiah FA, Sacks SL. New antiherpesvirus agents: their targets and therapeutic potential. Drugs. 1996;52: 17-32.
Chrisp P, Clissold SP. Foscarnet: a review of its antiviral activity, pharmacokinetic properties and therapeutic use in immunocompromised patients with cytomegalovirus retinitis. Drugs. 1991;41: 104-129.
Dwyer DE, Kesson AM. Advances in antiviral therapy. Curr Opin Pediatr. 1997;9: 24-30.
Noormohamed FH, Youle MS, Higgs CJ, Martin-Munley S, Gazzard BG, Lant AF. Pharmacokinetics and absolute bioavailability of oral foscarnet in human immunodeficiency virus-seropositive patients. Antimicrob Agents Chemother. 1998;42: 293-297.
Piketty C, Bardin C, Gilquin J, Mahe V, Kazatchkine MD, Chast F. Low plasma concentrations achieved with conventional schedules of administration of ganciclovir in patients with AIDS. J Infect Dis. 1996;174: 188-190.(Carmen M. Klass, Laurie T)