1 Institute of Biomedical Sciences, National Chung-Hsing University, Taichung, Taiwan
2 Division of Urology, Taichung Veterans General Hospital, No. 160, Section 3, Taichung-Gang Road, Taichung 40705, Taiwan
3 Department of Education and Research, Taichung Veterans General Hospital, No. 160, Section 3, Taichung-Gang Road, Taichung 40705, Taiwan
Correspondence
Chun-Jung Chen
cjchen{at}vghtc.gov.tw
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ABSTRACT |
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INTRODUCTION |
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Dehydroepiandrosterone (DHEA) and its sulfate ester (DHEAS), precursors of sex steroids, are found naturally in the blood as the most abundant circulating steroid hormones in humans. DHEA is a second adrenal-derived steroid and its serum level is known to exhibit an age-related decline (Majewska, 1995; Kroboth et al., 1999
). DHEA concentrations are particularly high in the brain, and DHEA and its related steroids can be synthesized de novo by brain neurons and astrocytes (Zwain & Yen, 1999
). DHEA is a widely studied hormone with multi-functional properties. It has been reported to produce beneficial effects in cancer, atherosclerosis, obesity, autoimmune diseases, infections, diabetes and ageing (Coleman et al., 1982
; Gordon et al., 1988
; Loria et al., 1988
; Nestler et al., 1988
; Rao et al., 1992
; Morales et al., 1994
; van Vollenhoven et al., 1994
; Bradley et al., 1995
; Daigle & Carr, 1998
). However, these wide-ranging activities of DHEA cannot be explained fully by activation of the androgen or oestrogen receptors. Furthermore, it is unknown whether all of the effects attributed to DHEA are mediated by DHEA or by its metabolites. Recent studies have pointed out alternative mechanisms by which DHEA exerts its biological action via non-steroid hormone receptors (Compagnone & Mellon, 1998
). DHEA also exerts multiple effects (e.g. neuroprotection, plasticity and memory enhancing) in the central nervous system, mediated through its non-genomic actions on neurotransmission, inflammation and oxidative stress (Majewska et al., 1990
; Compagnone & Mellon, 1998
; Kimonides et al., 1998
; Wolf & Kirschbaum, 1999
; Barger et al., 2000
).
The antiviral effects of DHEA-related hormones have been shown to exert an influence on influenza virus, herpes simplex virus (HSV), coxsackievirus B4, Feline immunodeficiency virus (FIV), human immunodeficiency virus (HIV) and West Nile virus (Loria et al., 1988; Ben-Nathan et al., 1991
, 1992
; Henderson et al., 1992
; Bradley et al., 1995
; Daigle & Carr, 1998
; Padgett et al., 2000
). Most studies have been conducted in animals, and the protective mechanisms induced by DHEA administration have been found to require an intact immune system. Although DHEA protects mice against lethal viral encephalitis (Ben-Nathan et al., 1991
), little is known about its effect on virus replication in a cell monolayer in the absence of an immune response. On the other hand, clinical studies indicate that the level of DHEA is lower in HIV-seropositive patients than the normal control and decreases continuously as the disease progresses (Jacobson et al., 1991
; Mulder et al., 1992
; Uozumi et al., 1996
). As DHEA is available as a nutritional supplement and has been administrated successfully to humans for a number of clinical syndromes (Coleman et al., 1982
; Gordon et al., 1988
; Loria et al., 1988
; Nestler et al., 1988
; Rao et al., 1992
; Morales et al., 1994
; van Vollenhoven et al., 1994
; Bradley et al., 1995
; Daigle & Carr, 1998
), its potential antiviral action is appreciated and merits further study. In the present study, we explored the effect of DHEA on JEV infection in neuroblastoma cells. We found that DHEA suppressed JEV replication and its cytotoxicity via a non-steroid hormone action. The mechanism of its antiviral action was largely by modulation of the MAPK signalling pathway.
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METHODS |
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Virus infection and titre determination.
To infect cells with JEV, monolayers were first adsorbed with JEV at an m.o.i. of 5 for 1 h at 37 °C. After adsorption, the unbound virus was removed by gentle washing with PBS, pH 7·4. Serum-free medium was added to each plate for further incubation at 37 °C. To determine viral titres, culture medium was harvested and used in a plaque assay (Chen et al., 2002). Briefly, various dilutions were added to 80 % confluent BHK21 cells and incubated at 37 °C for 1 h. After adsorption, cells were washed and overlaid with 1 % agarose (SeaPlaque; FMC BioProducts) containing RPMI 1640 plus 2 % FBS. After incubation for 4 days, cells were fixed with 10 % formaldehyde and stained with 0·5 % crystal violet.
Cytotoxicity assessment.
Cytotoxicity, as indicated by cell-membrane integrity, was assessed by measuring the activity of lactate dehydrogenase (LDH) in the culture medium by the colorimetric detection of formazan using an LDH diagnostic kit (Promega). After experiments, supernatants were transferred to a microtitre plate and incubated with reaction mixture at room temperature for 30 min for colour development. A492 was measured by using a spectrophotometer (PowerWaveX 340; Bio-Tek Instruments).
Western blot.
Protein extracts (50 µg) were resolved by SDS-PAGE and transferred on to a blotting membrane. The membrane was first incubated with 5 % skimmed milk in PBS for 30 min to reduce non-specific binding. Subsequently, the membrane was incubated with primary antibodies against JEV NS3 (diluted 1 : 5000), JEV NS5 (1 : 5000), -tubulin (1 : 1000; Sigma), extracellular signal-regulated kinase (ERK) (1 : 2000; Santa Cruz Biotechnology) and phospho-ERK (1 : 2000; Santa Cruz Biotechnology) overnight at 4 °C, followed by washing with 0·05 % Tween 20 in PBS. After washing, the membrane was incubated with horseradish peroxidase-conjugated secondary antibody. Signals were developed by chemiluminescent detection. The intensity of signals was determined by using a computer image system (IS1000, Alpha Innotech Corporation).
Slot-blot hybridization.
Isolation of total cellular RNA and slot-blot analysis were performed as described previously (Chen et al., 2002) with minor modifications. The probes used were the antigenomic strands of JEV RNA (nt 1039210976) and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) RNA that were synthesized in vitro with Sp6 RNA polymerase in the presence of Bio-11-UTP (Sigma). Signals were developed by chemiluminescent detection. The intensity of signals was determined by using a computer image system (IS1000, Alpha Innotech Corporation).
Plaque-reduction assays.
Plaque-reduction assays were carried out as reported previously (Shih et al., 2003). BHK21 cells in monolayers were infected at a virus concentration giving approximately 50100 plaques per monolayer and were compared with the virus control. DHEA was diluted and included in the agar-medium overlay. Plates were incubated at 37 °C for 4 days and stained with crystal violet, and the plaques were counted.
DNA agarose-gel electrophoresis.
DNA gel electrophoresis was performed as reported previously (Chen & Liao, 2003). Cells were lysed in 0·5 % Triton X-100, 5 mM Tris/HCl (pH 7·4), 20 mM EDTA at 4 °C for 30 min. After centrifugation, supernatants were extracted with phenol/chloroform and precipitated in ethanol. The resultant DNA (10 µg) was separated on a 1·5 % agarose gel and stained with ethidium bromide.
Flow-cytometry assay.
The cell-cycle distribution was analysed by flow cytometry (Chen & Liao, 2002). Briefly, cells were trypsinized, washed with PBS and fixed in 80 % ethanol. They were then washed with PBS, incubated with 100 µg RNase ml1 at 37 °C for 30 min, stained with 50 µg propidium iodide ml1 and analysed on a FACScan flow cytometer. The percentage of cells in different phases of the cell cycle was analysed by using CellFIT software (Becton Dickinson).
Statistical analysis.
Data were expressed as the mean±SEM. For comparisons, the statistical significance between means was determined by using one-way ANOVA followed by Dunnett's t-test. A level of P<0·05 was considered statistically significant.
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RESULTS |
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DHEA inhibits JEV-induced apoptosis
To understand further the mechanism by which DHEA prevented cell death in JEV-infected cells, several experiments were carried out involving apoptosis. DNA extracted from mock-infected N18 cells was found to be intact whereas, in JEV-infected cells, a characteristic internucleosomal ladder appeared. The addition of DHEA decreased the appearance of the apoptotic DNA ladder in a concentration-dependent manner (Fig. 3a). JEV-induced apoptosis was also analysed by flow cytometry. When JEV was added, N18 cells showed disruption of the normal distribution and a prominent new peak in fluorescence (Fig. 3b
). This peak, which represented the sub-G0/G1 phase, is characteristic of cells undergoing apoptosis. When DHEA alone was added to N18 cells, no such peak was observed. The JEV-induced alteration in normal distribution and appearance of the sub-G0/G1 phase were decreased by the presence of DHEA (Fig. 3b
). These findings indicated that DHEA inhibits JEV-induced apoptosis in N18 cells, including characteristic internucleosomal fragmentation and the appearance of the sub-G0/G1 phase.
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DISCUSSION |
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The exact physiological functions of DHEA are not fully known. DHEA is widely used as an inhibitor of glucose-6-phosphate dehydrogenase (G6PD) activity (Yang et al., 2000). Inhibition of G6PD effectively lowers the cellular pools of ribose 5-phosphate and ultimately results in the inhibition of ribonucleotide and deoxyribonucleotide synthesis. This inhibition may also result in a decrease in NADPH levels, a substrate necessary for the membrane-bound flavoprotein NADPH oxidase to generate superoxide anions (Sankarapandi et al., 1998
). Therefore, it is possible that the inhibition of JEV replication and JEV-induced cytotoxicity described herein is linked to the depletion of nucleotide substrates and superoxide-generation substrate. DHEA has been shown to exert its cytoprotective effect by ameliorating lipid peroxidation by a mechanism involving inhibition of hydroxyl radical production (Bastianetto et al., 1999
). The involvement of NADPH depletion and the resultant suppression of free radicals in the protective effect of DHEA against JEV were primarily excluded by the findings that free-radical scavenger compounds were ineffective at blocking JEV-induced cell death (Raung et al., 2001
). Both DHEA and DHEAS are potent inhibitors of G6PD (Gordon et al., 1995
). They have been shown to reverse chloroquine resistance in malaria infection via the inhibition of G6PD (Safeukui et al., 2004
). We found that DHEAS was unable to suppress JEV replication (Fig. 7
), indicating that direct inhibition of G6PD was not essential for the action of DHEA against JEV infection.
DHEA and related metabolites have been shown to exert regulatory effects on the immune system (Lucas et al., 1985). Administration of DHEA has been reported to protect against lethal viral infection, mostly in animals requiring an intact immune system. However, DHEA has also been found capable of suppressing replication of certain type of viruses, such as HIV (Loria et al., 1988
; Ben-Nathan et al., 1991
, 1992
; Henderson et al., 1992
; Bradley et al., 1995
; Daigle & Carr, 1998
; Padgett et al., 2000
). DHEA and DHEAS share similar activity in regulating malaria infection (Safeukui et al., 2004
). However, only DHEA was able to suppress FIV replication (Bradley et al., 1995
). The antiviral effect of androstenediol against HSV required the production of interferon (Daigle & Carr, 1998
). Therefore, in addition to diverse characteristics of viruses, DHEA seems to have direct physiological effects on some cell populations, leading to the suppression of virus replication.
Many viruses are known to manipulate host-signalling machinery to regulate virus replication and host-gene responses. Among them, MAPKs play important roles and their activities could be modulated in responding to virus infection. MAPKs, which consist of ERK, p38 protein kinase and c-Jun N-terminal kinase (JNK), are central components of signal-transduction pathways in the regulation of cell proliferation, differentiation, cytokine production and apoptosis (Karin, 1998). Several virus infections can induce the activation of MAPKs in infected cells and the ERK pathway has been implicated in the regulation of viral gene expression and replication in, for example, HIV, HSV, human cytomegalovirus, influenza virus and coxsackievirus (Jacqué et al., 1998
; Zachos et al., 1999
; Johnson et al., 2001
; Pleschka et al., 2001
; Luo et al., 2002
). Among the signalling molecules, the inhibition of ERK activity often results in loss of cell viability and apoptosis (Wang et al., 1998
). JEV infection resulted in a decrease in ERK phosphorylation (Fig. 5
) and in cell death (Figs 1 and 2
) and apoptosis (Fig. 3
). Previous studies have demonstrated that activation of MAPKs exerts a protective effect against JEV replication and its cytotoxicity (Liao et al., 2001
; Chen et al., 2002
). The activation of ERK can be modulated by DHEA on endothelial cells (Simoncini et al., 2003
). As shown in Fig. 5
, DHEA stimulation of the phosphorylation of ERK was concentration-dependent. Administration of DHEA reversed the JEV-induced decrease in ERK phosphorylation. This means that the cytoprotective effect of DHEA from JEV infection might be partly explained by the activation of ERK. To verify this assumption further, we found that the reversal effect from ERK inactivation and the antiviral effect of DHEA against JEV could be attenuated by U0126, an inhibitor of ERK (Fig. 6
). In addition, direct activation of ERK by anisomycin also markedly suppressed JEV-induced LDH efflux and ERK inactivation (Fig. 6c and d
). Inactive agents, such as DHEAS and pregnenolone, were unable to reverse JEV-induced ERK inactivation (Fig. 7
). Consistent with the failure of ICI 182780 and flutamide to block the antiviral effect of DHEA, they were also ineffective at abrogating the action of DHEA on ERK activation (Fig. 7
). Taken together, these results further demonstrate the role of ERK in the antiviral action.
Recently, Liao et al. (2001) demonstrated that the antiflavivirus effect of salicylates was partially reversed by blocking p38 MAPK activation. Chen et al. (2002)
also provided evidence showing the involvement of p38 MAPK and ERK in JEV-mediated cytotoxicity, as well as in the antiviral effect of salicylates. Here, we found that JEV-induced cytotoxicity was associated strongly with downregulation of ERK later in the course of infection (Fig. 5
). Transient activation of ERK by DHEA before JEV infection did not exhibit the antiviral effect. The delayed administration of DHEA well after viral infection gradually attenuated its antiviral effect (Fig. 4
). Despite the suppressive effect of DHEA, JEV infection still killed the infected cells after further cultivation (data not shown). Overall, DHEA treatment prolonged and/or delayed the onset of JEV-induced cytotoxicity rather than inhibiting it completely. An increasing body of evidence suggests that the dynamic balance between branches of the MAPKs regulates neuronal decisions to live or die in response to stressors (Xia et al., 1995
). In particular, ERK activation may play a pivotal role. For example, many trophic factors activate receptor tyrosine kinases, transmitting signals through the activation of ERK (Segal & Greenberg, 1996
). ERK activation appears to antagonize apoptotic pathways in some cell systems (Xia et al., 1995
). However, studies indicate that ERK activation may also play a pathological role in cells by responding to certain insults (Oh-hashi et al., 1999
; Stanciu et al., 2000
). Although the detailed mechanisms underlying the antiviral effect remain unclear, our current study provides experimental evidence demonstrating the importance of ERK activation on the antiviral effect of DHEA and suggests that the activation of ERK plays a role in host-cell defence against JEV infection.
In addition to the attenuation of cytotoxicity, DHEA ameliorated JEV replication in cells (Fig. 2). Activation of MAPKs by anisomycin also inhibited JEV replication (data not shown). Our findings and other previous reports (Liao et al., 2001
; Chen et al., 2002
) indicated that activation of MAPK signalling pathways might interfere with JEV replication. The cellular ERK pathway has been implicated in the regulation of viral gene expression and/or replication. The inhibition of ERK activation in visna virus-infected cells reduced expression of virus-specific proteins, resulting in inhibition of virus replication (Barber et al., 2002
). Similar inhibition interfered with the nuclear export of viral proteins, leading to a reduction in virus production (Pleschka et al., 2001
). In the HIV model, the activation of ERK augmented viral infectivity and replication via direct phosphorylation of viral proteins (Yang & Gabuzda, 1998
). In contrast, the antiviral effect of interleukin 1 against Hepatitis C virus was accompanied by an elevation of ERK activity (Zhu & Liu, 2003
). We also demonstrated a strong association between inhibition of JEV replication and ERK activation. It is not known at present how JEV replication is regulated by the ERK signalling pathway. Perhaps the activation of ERK initiates an antiviral cascade in the infected cells. Alternatively, ERK activity might modify and inactivate viral and/or host proteins necessary for the replication of JEV. Taken together, the diversity of ERK involvement suggests its importance either in a global virus strategy to enhance the replicative machinery or as a universal host-defence response to infection. The mechanisms involved in the virus specificity are not fully understood, although they are probably due to differences in the signalling pathways involved in the replication of each virus.
In conclusion, JEV infection induced inactivation of ERK later in the course of infection and caused apoptotic cell death. DHEA, through a non-genomic steroid-hormone mechanism, suppressed JEV replication and reduced JEV-induced cytotoxicity. Activation of ERK appeared to play a critical role in the antiviral effect of DHEA. On the basis of our observations, we conclude that the ERK signalling pathway involves an unidentified mechanism that restricts JEV replication.
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ACKNOWLEDGEMENTS |
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Received 21 April 2005;
accepted 5 June 2005.
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