- Original Articles
- Published:
Kaposi’s Sarcoma-Associated Herpesvirus Viral Interferon Regulatory Factor Confers Resistance to the Antiproliferative Effect of Interferon-α
Molecular Medicine volume 4, pages 402–412 (1998)
Abstract
Background
Kaposi’s sarcoma-associated herpesvirus (KSHV) encodes a 442 amino acid polypeptide-desig-nated viral interferon regulatory factor (vIRF) that displays homology to members of the interferon regulatory factor (IRF) family that bind to consensus interferon sequences and transactivate cellular genes that can modulate growth inhibition. Studies were conducted to determine whether vIRF affects the growth suppression mediated by interferon-α (IFN-α) in a human B lymphocyte cell line.
Materials and Methods
The human B lymphocyte cell line Daudi, which is sensitive to the antiproliferative effects of IFN-α, was stably transfected to express vIRF, and the proliferative response of vIRF expressing cells to IFN-α was compared with controls. The effect of vIRF on IRF-1 transactivation was analyzed by co-transfection of an IFN-±-responsive chloramphenicol acetyltransferase reporter and expression plasmids encoding IRF-1 and vIRF. Electrophoretic mobility shift assays were conducted to determine whether vIRF interferes with the DNA binding activity of IRF-1.
Results
Daudi human B lymphocyte cells expressing vIRF were resistant to the antiproliferative effects of IFN-α, whereas wild-type Daudi or Daudi cells transformed with vector DNA were growth inhibited by IFN-α. The activation of an interferon-responsive reporter by IFN-α or IRF-1 was repressed by expression of vIRF. IRF-1 DNA binding activity was unaffected by vIRF, and vIRF alone did not bind to the interferon consensus sequence.
Conclusions
These studies revealed that vERF functions to inhibit interferon-mediated growth control of a human B lymphocyte cell line by targeting IRF-1 transactivation of interferon-inducible genes. Since KSHV is a B lymphotropic herpesvirus associated with two forms of B lymphocyte neoplasms, these effects of vIRF likely contribute to B cell oncogenesis associated with KSHV infection.
Introduction
Kaposi’s sarcoma (KS)-associated herpesvirus (KSHV) or human herpesvirus-8 is associated with all epidemiological forms (AIDS-related, classical, post-transplant, and endemic) of Kaposi’s sarcoma (1–6). Epidemiological studies demonstrate that seroconversion to KSHV antibodies against virally encoded latent nuclear antigens occurs prior to the onset of KS (7–9) and that KSHV seropositivity is not common among the general population but is present in groups at risk for the development of KS (10–12). In KS biopsies, KSHV is present in endothelial cells and spindle cells (13–15), and viral gene expression is restricted; however, some cells are productively infected, as evidenced by the presence of viral particles (16) and by transmission of virus from KS biopsy material to cell lines susceptible to infection (17). In addition, KSHV infects CD19+ B lymphocytes (18, 19) and has been detected in cells of this lineage that were derived from body cavity-based lymphomas (20–22) and multicentric Castleman’s disease (23).
Sequencing of the KSHV genome (24) revealed similarity to gammaherpesviruses. These include herpesvirus saimiri, which causes fulminate T lymphomas in primates other than its natural host, the squirrel monkey (reviewed in ref. 25), and Epstein-Barr virus (EBV), which is associated with nasopharyngeal carcinoma and Burkitt’s lymphoma (reviewed in ref. 26). The herpesvirus saimiri transformation-associated protein of strain C (Stp-C) (27, 28) and the EBV nuclear antigens (EBNAs) and latent membrane proteins (LMPs) contribute to immortalization and/or transformation by these herpesviruses. Interestingly, KSHV does not encode proteins with homology to either herpesvirus saimiri or EBV transformation-associated proteins; however, KSHV does encode proteins that may affect cellular signaling pathways and the regulation of cell growth (24). For example, expression of the KSHV homologue of human cyclin D in cultured cells induces phosphorylation and inactivation of the retinoblastoma tumor suppressor protein (29, 30). The KSHV homologue of bcl-2 inhibits bax-mediated apoptosis (31), and KSHV ORF K13, based on its homology with other viral proteins with anti-apoptotic properties, may function to inhibit Fas and tumor necrosis factor-1 (TNF-1) receptor signaling pathways that induce programmed cell death (32, 33). In addition, the KSHV homologue of interleukin-6 (IL-6) (vIL-6) supports the growth of IL-6-de-pendent cell lines that undergo apoptosis in the absence of IL-6 (18). vIL-6 gene expression has been detected in KSHV-infected dendritic cells derived from multiple myeloma patients, suggesting that KSHV may play a role in multiple myeloma via paracrine stimulation of bone marrow plasma cells by vIL-6 (34).
Another KSHV polypeptide that may affect cellular signaling pathways is viral IFN regulatory factor (vIRF) encoded by ORF K9; this viral protein displays homology to members of the IFN regulatory factor family (IRFs; 35, 36). In response to cytokines such as class I or class II IFNs or virus infection, IRFs regulate transcription of a broad range of genes involved in immune regulation, cell growth control, and the establishment of an antiviral state (reviewed in ref. 36). IFN regulatory factor-1 (IRF-1) binds to the IFN consensus sequence [ICS; (G/A)(G/C) TTTC] and activates transcription of IFN-inducible genes such as IFN-α and IFN-β (37). IRF-2 and IRF-1 possess homologous amino-terminal DNA binding domains, and IRF-2 binds to the IFN-α ICS with affinity equivalent to that of IRF-1 (38)-IRF-2 and functions to repress expression of IFN-inducible genes by competing with IRF-1 for ICS binding sites with equal affinity (35, 38, 39). Two other members of the IRF family, IFN consensus sequence-binding protein (ICSBP) and IFN consensus sequence-binding protein of activated T lymphocytes (ICSAT) function to repress gene expression induced by IRF-1 or IFNs. Thus, IFN-stimulated gene expression mediated by IRF-1 is controlled negatively by multiple IRFs. Recent studies have revealed that KSHV vIRF inhibits IFN signaling in a manner similar to that of the cellular repressor IRFs (40, 41). These studies demonstrated that transient expression of vIRF inhibited IFN- or IRF-1-mediated activation of an IFN-inducible promoter. Importantly, NIH3T3 cells stably expressing vIRF were shown to display characteristics of transformed cells, and injection of these cells into nude mice induced tumor formation (41). Thus, vIRF is a transforming oncogene that may play a role in KSHV-associated neoplasms. Analyses of viral gene expression have revealed that vIRF is not expressed in Kaposi’s sarcoma lesions but it is expressed in cell lines derived from body cavity-based lymphomas (18, 41). The studies described in this report address whether vIRF functions to inhibit IFN signaling pathways in a cell type that is relevant to KSHV cell tropism. These studies revealed that KSHV vIRF confers resistance to the antiproliferative effects of IFN-α in B lymphocytes.
Materials and Methods
Plasmids
A KSHV vIRF expression construct was generated by polymerase chain reaction (PCR) amplification of a, DNA fragment encoding the K9 open reading frame using as template total cellular DNA isolated from the KSHV-infected cell line BCBL-1 (22). The sense primer (5′-TTTTTT GGATCCACCATGGACCCAGGCCAAAGACCGA CCCCTTTT-3′) contained a BamHI restriction site and a Kozak sequence for translation initiation (42), while the anti-sense primer (5′-TTTTTTAA GCTTTTGCATGGCATCCCATAACGGCTTCGG3’) contained a HindIII restriction site. Following restriction endonuclease digestion, the PCR product was cloned into the expression vector pMYCHIS (Invitrogen, San Diego, CA) to generate plasmid pK9MH; vIRF encoded by pK9MH contained a myc-epitope and a polyhistidine tag at the carboxyl terminus. DNA sequence analyses of both strands of pK9MH confirmed that the PCR-generated DNA fragment matched the published sequence of the K9 open reading frame (24). A cDNA encoding human IRF-1 was amplified by PCR using as template human spleen cDNA (GIBCO BRL, Gaithersburg, MD). The IRF-1 cDNA was cloned into a modified pcDNA3 (Invitrogen) which contains the hemagglutinin (HA) epitope, and the resulting clone, pIRF-IHA, encodes IRF-1 with an HA epitope at the amino terminus.
Expression of Recombinant Proteins
pK9MH or pIRF-IHA DNAs were transcribed and translated in vitro using TNT T7 Quick reaction rabbit reticulocyte lysates (Promega, Madison, WI) either in the presence or absence of 35S-methionine according to the manufacturer’s instructions. Labeled polypeptides were analyzed by fractionation on 12% SDS-PAGE. Immuno-precipitations were conducted using 0.5 µg of murine monoclonal anti-myc antibody 9E10 or isotype control antibody (IgG1; Sigma, St. Louis, MO) with 20 µl of in vitro translation reaction in 200 µl of association buffer (50 mM Tris-Cl, pH 7.4, 250 mM NaCl, 1% Nonidet P-40, 1 mM dithiothreotol, and 1× concentration of protease inhibitor cocktail. Complete; Boehringer Mannheim Biochemicals, Indianapolis, IN). Antigen-antibody complexes were adsorbed to protein G-agarose beads (GIBCO, BRL), washed three times with association buffer, and analyzed by SDS-PAGE. Immunoblot analyses were conducted to detect recombinant proteins in total cell extracts derived from 0.5 × 106 cell equivalents. Following transfer of proteins from SDS-PAGE to Genescreen membranes, the filters were incubated with anti-myc antibody diluted 1:800 followed by secondary antibody conjugated to horseradish peroxidase and diluted 1:5000. Proteins were visualized using the enhanced chemiluminescence assay (Amersham, Arlington Heights, IL). Blocking and washing of filters were conducted according to the manufacturer’s recommendations.
Cells and Transfections
Human embryonic 293, HeLa, and NIH3T3 cells were maintained in Dulbecco’s minimal essential medium (DMEM) supplemented with penicillin (100 U/ml), streptomycin (100 mg/ml), and 5% fetal bovine serum (FBS). The calcium phosphate precipitation method (43) was used to transfect 293 cells, and cell lysates were harvested 48 hr post-transfection. HeLa and NIH3T3 cells were transfected using Fugene-6 transfection reagent as recommended by the supplier (Boehringer Mannheim Biochemicals). In CAT reporter assays, cell monolayers were harvested 24 hr after infection and CAT activity was quantitated. For reporter assays of cells stimulated with IFN, cells were transfected for 12 hr then incubated for an additional 12 hr with recombinant IFN-α2b (Schering Corporation, Kenilworth, NJ). To correct for transfection efficiency, 3εg of RSV-β-GAL was co-transfected in each sample, and the amount of extract used in CAT assays was normalized according to the level of β-galactosidase activity (43).
Cell Lines Expressing vIRF and Anti-Proliferation Assays
Ten micrograms of linear pK9MH or pMYCHIS DNAs and 2 × 106 Daudi B lymphocyte cells (ATCC; ccl-213) in 0.4-cm cuvettes were pulsed using a Bio-Rad Gene puiser with settings of 220 V and 960 µF. Twenty-four hours after electroporation, geneticin (G418; Sigma) was added to the culture medium at a final concentration of 1.5 mg/ml (active concentration). Cultures were maintained in G418 selection unless employed for experimentation. For the antiproliferation assay, wild-type Daudi cells or cells transformed with pK9MH or vector DNAs were plated at a density of 4 × 104 cells per well in 96-well microliter plates. The experiment was initiated by the addition of recombinant IFN-α2b, and cultures received additional medium supplemented with IFN-α2b on day 3. Cell number was determined microscopically on days 3 and 5.
Electrophoretic Mobility Shift Assay
DNA binding activity of vIRF or IRF-1 was analyzed by electrophoretic mobility gel shift assay (EMSA) using as probe a double-stranded oligonucleotide containing the PRDI site of the IFN-α promoter (sense-GGGAGAAGTGAAAGTG; anti-sense-CACTTTCACTTCTCCC) radiolabeled with (γ-32P)ATP. Four microliters of in vitro transcription and translation reaction charged with either pK9MH or pIRF-IHA and 1 nm of probe was incubated in binding buffer (10 mM Tris-Cl, pH 7.5, 50 mM NaCl, 1 mM EDTA, 1 mM DIT, 4% glycerol, 0.5% Nonidet P-40, and 1 µm of polydeoxycytosine/inosine) for 30 min at room temperature (44). The specificity of binding was analyzed using a 10-fold excess of competitor oligonucleotides. Protein-DNA complexes were analyzed by electrophoresis through 4% nonde-naturing Polyacrylamide in 0.5× Tris-borate-EDTA buffer (45).
Results
Expression of vIRF In Vitro and In Vivo
To examine expression of vIRF, a plasmid encoding this gene product was employed as template in a coupled in vitro transcription and translation reaction using rabbit reticulocyte lysates (Promega) in the presence of 35S-methionine. SDS-PAGE analysis of the translation product revealed a band migrating at 53 kD (Fig. 1A, lane 4), which corresponds in size to the predicted molecular weight of the epitope-tagged K9 ORF. A 53-kD polypeptide was not observed in reactions using vector DNA as template (Fig. 1 A, lane 1). The presence of the myc-epitope in vIRF was confirmed by immunoprecipitation with antimyc antibody (Boehringer Mannheim Biochemicals) from the pK9MH-charged reaction (Fig. 1 A, lane 6) but not from the vector DNA template reaction (Fig. 1A, lane 3). Isotype-matched control antibody did not immunoprecipitate the 53-kD vIRF from reactions using either vector or pK9MH DNAs as template (Fig. 1A, lanes 2 and 5, respectively). Expression of vIRF was analyzed by transient transfection of the pK9MH vIRF expression vector into the human embryonic kidney cell line, 293. Subconfluent monolayers of 293 cells were transfected with either a negative control vector alone or with different amounts of vIRF expression vector. Thirty-six hours after transfection, monolayers were harvested and cell lysates were analyzed by immunoblot analysis using anti-myc antibody followed by anti-mouse antibody conjugated to horseradish peroxidase. The 53-kD vIRF was detected in lysates from pK9MH-transfected cells (Fig. 1B, lane 2) but not from cells transfected with vector DNA (Fig. 1B, lane 1). The levels of vIRF observed in pK9MH-transfected cells corresponded to the amount of plasmid used in each transfection (Fig. 1B, lanes 2–4). Daudi B lymphocyte cells stably transformed with pK9MH (vIRF) were analyzed by immunoblotting of cell lysates for the expression of vIRF. Using anti-myc antibody, the 53-kD vIRF was detected in lysates from Daudi/vIRF transformed cells (Fig. 1C, lane 2). No signal corresponding to the 53-kD protein was observed in cell lysates from cells transformed with plasmid vector (Control; Fig. 1C, lane 1).
vIRF Suppresses the Anti-proliferative Response of Cells to IFN
Because of the homology of vIRF with members of the IRF family (18, 19), the capacity of vIRF to alter the sensitivity of cells to IFN-α was analyzed. The Burkitt’s lymphoma cell line Daudi is latently infected with EBV and is sensitive to growth inhibition by IFN-α (46, 47). For the antiproliferation assay, Daudi/vIRF or Daudi/vector cells were incubated with increasing concentrations of recombinant IFN-α2b (Schering Corporation, Kenilworth, NJ). Three or five days after the addition of IFN-α2b, cells in each culture were enumerated; the data are presented as a percent of the cell number of the IFN-free controls (Fig. 2). On day 3, the lowest concentration of IFN-α2b (0.5 U/ml) substantially reduced the proliferation of control Daudi cells (triangles) relative to proliferation in the absence of IFN (Fig. 2A). At higher concentrations of IFN-α2b, proliferation of Daudi/vector cells was reduced to less than 10%. The specificity of the antiproliferative effects of IFN-α2b on Daudi cells was demonstrated by the lack of growth inhibition of the B lymphocyte cell line BJAB (squares), which did not respond to IFN-α2b in this assay. In contrast to controls, the proliferation of Daudi/vIRF cells (circles) was greater than 80% at IFN-α2b concentrations of 0.5 and 5.0 U/ml. The resistance of Daudi/vIRF cells to the antiproliferative effects of IFN-α2b was partially overcome at concentrations of 50 and 500 U/ml IFN-α2b. The proliferation of Daudi/vIRF cells at 5 days after IFN treatment showed a pattern of resistance similar to that observed after 3 days of IFN treatment except that the growth of Daudi/ vIRF cells at concentrations of 50 and 500 U/ml of IFN-α2b was even greater at 5 days versus 3 days of IFN-α2b treatment (Fig. 2B). This is likely due to the degradation of IFN in the cell culture over time and subsequent growth of Daudi/vIRF cells in the pooled population of transformed cells that express high levels of vIRF. No differences in the growth rate of Daudi/vector and Daudi/vIRF cells were observed in the absence of IFN-α2b (data not shown), thus eliminating the possibility that Daudi/vIRF cells have an inherently higher rate of proliferation than the parental or Daudi/vector cells. Furthermore, the number of nonviable cells in the IFN-α-treated cultures compared with the interferon-free controls was not significantly different, suggesting that IFN-α affected the rate of proliferation rather than cell viability. These data demonstrate that expression of vIRF in a human B lymphocyte cell line can overcome the growth-suppressive effect of IFN-α.
vIRF Inhibits IFN-Mediated Activation of the IFN-β Promoter
To examine the molecular basis of vIRF-mediated inhibition of the cellular response to IFN-α, the capacity of vIRF to affect activation of the IFN-responsive promoter IFN-β was analyzed. HeLa cells were transfected with the reporter construct IFN-β-CAT (48), and 24 hr post-transfection the cells were treated with IFN-α2b. Twelve hours after IFN-α2b treatment, the cells were harvested and CAT activity was quantitated. Cells transfected with IFN-β-CAT and incubated with 100 U/ml of IFN-α2b resulted in ~ 10-fold activation of the IFN-β promoter (Fig. 3A). In contrast, vIRF-transfected cells showed substantially diminished IFN-β-CAT activity in response to IFN-α2b treatment. Inhibition of IFN-β promoter by vIRF expression was observed even when 10,000 U/ml IFN-α2b was employed. A reduction in IFN-β promoter activity was not observed when vector plasmid DNA was substituted for vIRF plasmid, demonstrating that inhibition was not due to promoter competition from input DNAs.
Inhibition of IRF-1-Dependent Transactivation by vIRF
The cis-acting sequences within the IFN-β promoter/enhancer region that are responsible for activation by IFN have been well defined (reviewed in ref. 36). The positive regulatory domain I (PRDI) contains four tandemly repeated IRF-1 binding sites that are responsible for IRF-1 binding and transactivation in response to viral infection or IFN-α signaling (37, 49). To determine whether vIRF inhibits IFN-α signaling by affecting the function of IRF-1, HeLa cells were co-transfected with IFN-β-CAT reporter, the pK9MH vIRF expression vector, or an IRF-1 expression vector plasmid, pIRF-1. That IRF-1 transactivates the IFN-β promoter was shown by co-transfection of the IFN-β-CAT reporter with pIRF-IHA, resulting in a 5- to 7-fold increase in CAT activity (Fig. 3B). When increasing amounts of vIRF expression vector plasmid were co-transfected with pIRF-1 expression plasmid, the levels of CAT activity were reduced in a dose-dependent fashion. When vector DNA was substituted for the vIRF expression vector, no inhibition of pIRF-IHA transactivation was observed.
One possibility for the inhibition of IRF-1-mediated activation was that expression of vIRF induced a general inhibition of transcription. To eliminate this possibility, the effects of vIRF were analyzed using as an IRF-1-independent reporter, RSV-CAT, in which the Rous sarcoma virus (RSV) promoter directs expression of the CAT gene. RSV-CAT was unresponsive to IRF-1 as shown by co-transfection of HeLa cells with pRSV-CAT and pIRF-1 DNAs (Fig. 3C). The vIRF expression vector, alone or in combination with pIRF-1, did not reduce CAT activity, thus demonstrating that vIRF does not inhibit gene expression nonspecifically.
vIRF Does not Affect IRF-1 DNA Binding Activity
Electrophoretic mobility shift assays were conducted to determine whether vIRF could inhibit the binding of IRF-1 to the ICS. As expected, IRF-1 translated in vitro binds to the ICS, as seen by the shift of radiolabeled probe to a slower migrating form (Fig. 4; lanes 1 versus 2). IRF-1 binding activity was specific for pIRF-IHA template in vitro transcription and translation reactions since reactions programmed with vector DNA did not possess ICS binding activity (Fig. 4, lane 1). The specificity of IRF-1 binding was demonstrated by competition of IRF-1 binding with cold ICS oligonucleotide (Fig. 4, lane 4) and by the lack of competition of IRF-1 binding with cold mutant ICS oligonucleotide (Fig. 4, lane 3). Unlike IRF-1, no binding activity was detected for vIRF (Fig. 4, lane 5). Furthermore, IRF-1 binding activity was not affected by the presence of vIRF (Fig. 4, compare lanes 2 and 6). These data suggest that inhibition of IRF-1 transactivation function by vIRF involves protein-protein interactions that do not result in competition for binding to DNA target sites.
Discussion
In response to stimulation of cells with IFN-α or to virus infection, the cellular transcriptional transactivator IRF-1 increases expression of a panoply of IFN-responsive genes. One consequence of IRF-1-mediated gene activation is the inhibition of cell proliferation, as ectopic overexpression of IRF-1 suppresses cell growth in several cell types (50, 51). In this report, KSHV vIRF was demonstrated to confer resistance to growth suppression by IFN-α in a human B lymphocyte cell line, to inhibit activation of an IFN-responsive promoter by stimulation of cells with IFN-α, and to repress IRF-1-dependent transactivation. IRF-1 transactivation is subject to regulation by other IRF family members that share homology within an amino-terminal DNA binding domain (35). IRF-2 and ICSAT repress IRF-1 transactivation function by competition for ICS binding sites (37–39, 52). Repression of IRF-1 function by ICSBP may involve protein-protein interactions between ICSBP and IRF-1 (53, 54) or competition with IRF-1 for ICS binding sites (55, 56). The molecular mechanism by which vIRF inhibits IRF-1 function is apparently novel as these studies did not reveal interactions between vIRF and IRF-1 (data not shown) nor binding activity of vIRF to the ICS (Fig. 4). A recent study has also reported that vIRF inhibits both IFN responses and IRF-1-mediated transactivation (40), as described here. In concordance with the studies described in this report, vIRF did not inhibit IRF-1 binding to DNA nor did vIRF bind directly to IRF-1 (40). These data suggest that vIRF may employ a mechanism of repression that differs from that of cellular IRF family members.
The recent findings that vIRF is a transforming oncoprotein when assayed in murine fibroblasts suggests that vIRF may play a role in the induction of tumorigenesis in vivo. vIRF gene expression has been detected in cell lines derived from BCBL but not KS tumor tissues, raising the possibility that vIRF may contribute to the induction of B lymphomas associated with KSHV. The EBV EBNA-2 polypeptide, when expressed in Daudi cells or in EBV-negative Burkitt’s lymphoma cell lines, imparts resistance to IFN-α-mediated growth inhibition (46), a function similar to that described for vIRF. EBNA-2 may affect IFN signaling by decreasing levels of ISGF3 (47), a complex of three polypeptides (STAT-1, STAT-2, and p48) that activates promoters containing the IFN-stimulated response element. The observation that vIRF inhibited activation of the interferon-stimulated response element by IRF-1 more effectively than the interferon-stimulated response element by IFN-α suggests that vIRF may show relative specificity for IRF-1, rather than p48-STAT-1-STAT-2, activation. Thus, EBV and KSHV, two B lymphotropic herpesviruses, have encoded viral proteins whose function is to suppress growth inhibition by IFN-α, albeit by targeting different components of IFN-signaling pathways. Interestingly, EBNA-2 in conjunction with other EBV proteins is required for the immortalization of primary B lymphocytes (57). The association of KSHV with two B lymphocyte neoplasms, body cavity-based lymphoma and multicentric Castleman’s disease (20-23), suggests that KSHV may cause dysregulation of B lymphocyte proliferation in part through this mechanism.
The expression of a viral protein capable of inhibiting IRF-1-mediated activation of IFN-responsive genes may provide KSHV with an advantage in countering cellular responses to viral infection. Gene targeting of IRF-1 revealed that IRF-1-deficient mice are less resistant to infection by encephalomyocarditis virus infection (58). In addition, IRF-1 is implicated in the activation of immune response genes such as class I histocompatibility antigens and in the activation of regulators of cell growth such as p21, doublestranded RNA-dependent protein kinase (PKR), and 2′5′-oligoadenylate synthetase (35). IRF-1 plays a role in programmed cell death since normal embryonic fibroblasts, but not IRF-l−/− embryonic fibroblasts, undergo apoptosis in response to expression of oncogenic ras combined with a block to cell proliferation (59). Also, IRF-1 is required for DNA damage-induced apoptosis of mature T lymphocytes (60). Thus, IRF-1 plays a role in the regulation of cell proliferation, the immune response, and programmed cell death, all of which are potential responses to viral infection.
IRF-1 has tumor-suppressor functions, since activated c-H-ras is sufficient to transform embryonic fibroblasts from IRF-1-deficient mice but is not sufficient to transform normal embryonic fibroblasts. Deletions within the IRF-1 locus have been identified in leukemias and myelodysplastic syndrome, suggesting that loss of IRF-1 anti-on-cogenic function may be associated with tumorigenicity in vivo (61). The findings that vIRF inhibits the transactivation function of IRF-1 (40, 41), a known tumor suppressor protein, that vIRF transforms NIH3T3 cells (41), and that vIRF confers resistance to IFN-α-mediated suppression of cell growth in a cell type relevant to KSHV infection suggest that expression of vIRF in KSHV-infected B lymphocytes may affect numerous cellular responses to viral infection and/or cytokine stimulation, including cellular transformation.
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Acknowledgments
We thank Ms. Donna Gschwend and Ms. Nancy Barrett for manuscript preparation. This work was supported in part by a grant from the National Institutes of Health (CA46592).
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Communicated by J. Leiden.
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Flowers, C.C., Flowers, S.P. & Nabel, G.J. Kaposi’s Sarcoma-Associated Herpesvirus Viral Interferon Regulatory Factor Confers Resistance to the Antiproliferative Effect of Interferon-α. Mol Med 4, 402–412 (1998). https://doi.org/10.1007/BF03401747
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DOI: https://doi.org/10.1007/BF03401747