Inducible Guanylate-Binding Protein 7 Facilitates Influenza A Virus Replication by Suppressing Innate Immunity via NF-κB and JAK-STAT Signaling Pathways.

Guanylate-binding protein 7 (GBP7) belongs to the GBP family, which plays key roles in mediating innate immune responses to intracellular pathogens. Thus far, GBP7 has been reported to be a critical cellular factor against bacterial infection. However, the relationship between GBP7 and influenza A virus (IAV) replication is unknown. Here, we showed that GBP7 expression was significantly upregulated in the lungs of mice, human peripheral blood mononuclear cells (PBMCs), and A549 cells during IAV infection. Using the CRISPR-Cas9 system and overexpression approaches, it was found that GBP7 knockout inhibited IAV replication by enhancing the expression of IAV-induced type I interferon (IFN), type III IFN, and proinflammatory cytokines. Conversely, overexpression of GBP7 facilitated IAV replication by suppressing the expression of those factors. Furthermore, GBP7 knockout enhanced IAV-induced nuclear factor-κB (NF-κB) activation and phosphorylation of stat1 and stat2; overexpression of GBP7 had the opposite effect. Our data indicated that GBP7 suppresses innate immune responses to IAV infection via NF-κB and JAK-STAT signaling pathways. Taken together, upon IAV infection, the induced GBP7 facilitated IAV replication by suppressing innate immune responses to IAV infection, which suggested that GBP7 serves as a therapeutic target for controlling IAV infection.IMPORTANCE So far, few studies have mentioned the distinct function of guanylate-binding protein 7 (GBP7) on virus infection. Here, we reported that GBP7 expression was significantly upregulated in the lungs of mice, human PBMCs, and A549 cells during IAV infection. GBP7 facilitated IAV replication by suppressing the expression of type I interferon (IFN), type III IFN, and proinflammatory cytokines. Furthermore, it was indicated that GBP7 suppresses innate immune responses to IAV infection via NF-κB and JAK-STAT signaling pathways. Taken together, our results elucidate a critical role of GBP7 in the host immune system during IAV infection.

Bclaf1 critically regulates the type I interferon response and is degraded by alphaherpesvirus US3.

Type I interferon response plays a prominent role against viral infection, which is frequently disrupted by viruses. Here, we report Bcl-2 associated transcription factor 1 (Bclaf1) is degraded during the alphaherpesvirus Pseudorabies virus (PRV) and Herpes simplex virus type 1 (HSV-1) infections through the viral protein US3. We further reveal that Bclaf1 functions critically in type I interferon signaling. Knockdown or knockout of Bclaf1 in cells significantly impairs interferon-α (IFNα) -mediated gene transcription and viral inhibition against US3 deficient PRV and HSV-1. Mechanistically, Bclaf1 maintains a mechanism allowing STAT1 and STAT2 to be efficiently phosphorylated in response to IFNα, and more importantly, facilitates IFN-stimulated gene factor 3 (ISGF3) binding with IFN-stimulated response elements (ISRE) for efficient gene transcription by directly interacting with ISRE and STAT2. Our studies establish the importance of Bclaf1 in IFNα-induced antiviral immunity and in the control of viral infections.

STAT1 facilitates oestrogen receptor α transcription and stimulates breast cancer cell proliferation.

Oestrogen receptor α (ERα) is overexpressed in two-thirds of all breast cancer cases and is involved in breast cancer development and progression. Although ERα -positive breast cancer can be effectively treated by endocrine therapy, endocrine resistance is an urgent clinical problem. Thus, further understanding of the underlying mechanisms involved in ERα signalling is critical in dealing with endocrine resistance in patients with breast cancer. In the present study, unbiased RNA sequence analysis was conducted between the MCF-7 and MCF-7 tamoxifen-resistant (LCC2) cell lines in order to identify differentially expressed genes. The whole transcriptomic data indicated that the JAK-STAT pathway is markedly up-regulated, particularly the ISGF3 complex. As the critical effectors, STAT1 and IRF9 were up-regulated 5- and 20-fold, respectively, in LCC2 cells. The biological experiments indicated that STAT1 is important for ERα signalling. Depletion of STAT1 or inhibition of STAT1 function significantly decreased levels of ERα protein, ERα -target gene expression and cell proliferation in both the MCF-7 and LCC2 cell lines. Chromatin immunoprecipitation revealed that ERα transcription is associated with STAT1 recruitment to the ERα promoter region, suggesting that transcriptional regulation is one mechanism by which STAT1 regulates ERα mRNA levels and ERα signalling in breast cancer cells. The present study reveals a possible endocrine-resistant mechanism by which STAT1 modulates ERα signalling and confers tamoxifen resistance. Targeting of STAT1 is a potential treatment strategy for endocrine-resistant breast cancers.

Suppression of Mcl-1 induces apoptosis in mouse peritoneal macrophages infected with Mycobacterium tuberculosis.

The effect of myeloid cell leukemia-1 (Mcl-1) inhibition on apoptosis of peritoneal macrophages in mice infected with Mycobacterium tuberculosis was investigated and the primary signaling pathway associated with the transcriptional regulation of Mcl-1 was identified. Real-time PCR and western blotting indicated that Mcl-1 transcript and protein expression are upregulated during infection with virulent M. tuberculosis H37Rv and Xinjiang strains but not with attenuated M. tuberculosis strain H37Ra or Bacillus Calmette-Guérin. Mcl-1 transcript and protein expression were downregulated by specific inhibitors of the Janus kinase/signal transducer and activator of transcription (JAK/STAT), mitogen-activated protein kinase (MAPK) and phosphoinositol 3-kinase (PI3K) pathways (AG490, PD98059 and LY294002, respectively). The strongest inhibitor of Mcl-1 expression was PD98059, the MAPK inhibitor. Flow cytometry demonstrated that the rate of apoptosis in peritoneal macrophages is significantly higher in mice infected with M. tuberculosis and the rate of apoptosis is correlated with the virulence of the strain of M. tuberculosis. Apoptosis was found to be upregulated by AG490, PD98059 and LY294002, whereas inhibition of the MAPK pathway sensitized the infected macrophages to apoptosis. Taken together, these results suggest that specific downregulation of Mcl-1 significantly increases apoptosis of peritoneal macrophages and that the MAPK signaling pathway is the primary mediator of Mcl-1 expression.

The type I interferon signaling pathway is a target for glucocorticoid inhibition.

Type I interferon (IFN) is essential for host defenses against viruses; however, dysregulated IFN signaling is causally linked to autoimmunity, particularly systemic lupus erythematosus. Autoimmune disease treatments rely on glucocorticoids (GCs), which act via the GC receptor (GR) to repress proinflammatory cytokine gene transcription. Conversely, cytokine signaling through cognate Jak/STAT pathways is reportedly unaffected or even stimulated by GR. Unexpectedly, we found that GR dramatically inhibited IFN-stimulated gene (ISG) expression in macrophages. The target of inhibition, the heterotrimeric STAT1-STAT2-IRF9 (ISGF3) transcription complex, utilized the GR cofactor GRIP1/TIF2 as a coactivator. Consequently, GRIP1 knockdown, genetic ablation, or depletion by GC-activated GR attenuated ISGF3 promoter occupancy, preinitiation complex assembly, and ISG expression. Furthermore, this regulatory loop was restricted to cell types such as macrophages expressing the GRIP1 protein at extremely low levels, and pharmacological disruption of the GR-GRIP1 interaction or transient introduction of GRIP1 restored RNA polymerase recruitment to target ISGs and the subsequent IFN response. Thus, type I IFN is a cytokine uniquely controlled by GR at the levels of not only production but also signaling through antagonism with the ISGF3 effector function, revealing a novel facet of the immunosuppressive properties of GCs.

Interferon tau: a novel pregnancy recognition signal.

PROBLEM: Trophectoderm of ruminant conceptuses (embryo and associated membranes) secretes tau interferons (IFNtau) as the pregnancy recognition signal. How does it act? METHOD: Review of current data. RESULTS: IFNtau acts on uterine epithelium to suppress transcription of the genes for estrogen receptor and oxytocin receptor. This blocks development of the uterine luteolytic mechanism and, therefore, release of luteolytic pulses of prostaglandin F2alpha, but it has no effect on expression of the progesterone receptor. Maintenance of progesterone secretion by the corpus luteum ensures establishment and maintenance of pregnancy. Secretion of IFNtau on days 12-15 for sheep and days 14-17 for cows and goats is essential for pregnancy recognition. CONCLUSION: We propose that IFNtau affects endometrial gene expression by activating the Jak/Stat pathway, which results in formation of the ISGF3alpha transcription factor complex. ISGF3alpha binds to interferon-stimulated response elements and activates transcription of interferon-responsive genes such as interferon regulatory factor-1 (IRF-1) which, in turn, activates expression of the negative-acting transcription factor IRF-2. Pregnancy (or intrauterine injection of roIFNtau) results in a transient increase in endometrial IRF-1 expression followed 36-48 hr later by a sustained increase in IRF-2. We propose that IRF-2, or an IFNtau-induced negative regulatory factor like IRF-2, suppresses expression of the estrogen receptor gene and directly or indirectly blocks expression of the gene for oxytocin receptor to abrogate the uterine luteolytic mechanism and ensure the establishment of pregnancy.

Interferon alpha (IFN alpha) signaling in cells expressing the variant form of the type I IFN receptor.

Two different Type I interferon receptors (IFN-R) have been described: the normal and the variant receptors. The alpha subunit of the Type I IFN-R has a molecular mass of 110 kDa in cells expressing normal and variant receptors. The beta subunit has a molecular mass of approximately 100 kDa in cells that express normal receptors and 55 kDa in cells expressing the variant form of the receptor. The IFN alpha-resistant U-937 cell line expresses variant receptors and fails to down-regulate and phosphorylate the alpha subunit on tyrosine residues. We report that two other myelomonocytic cell lines, YK-M2 and ML-2, also expressing the variant form of the receptor, fail to down-regulate and phosphorylate the alpha subunit on tyrosine residues. However, YK-M2 and ML-2 cells are sensitive to the antiproliferative and antiviral effects of IFN alpha 2, indicating that phosphorylation of the alpha subunit is not necessary to elicit an IFN alpha response and that expression of variant receptors is not a source of IFN alpha resistance. We also determined if other proteins involved in the IFN alpha signal transduction pathway had a different phosphorylation pattern. Treatment of cells expressing variant receptors induced tyrosine phosphorylation of the p135tyk2 tyrosine kinase, and the three interferon-stimulated gene factor 3 alpha (ISGF3 alpha) polypeptides (p113, p91, and p84), albeit at lower levels. These results indicate that cells expressing either form of the Type I IFN-R phosphorylate a similar set of proteins, with the exception of the alpha subunit.

The genomic structure of the murine ICSBP gene reveals the presence of the gamma interferon-responsive element, to which an ISGF3 alpha subunit (or similar) molecule binds.

ICSBP, a member of the interferon regulatory factor family, is expressed predominantly in lymphoid tissues and is induced by gamma interferon (IFN-gamma). We have studied the genomic organization of the murine ICSBP gene and its 5' upstream region. The murine ICSBP gene (Icsbp) is present as a single copy on chromosome 8 and consists of nine exons. Transcription initiates at two juxtaposed sites downstream from the TATA and CAAT boxes and produces two species of ICSBP mRNA (3.0 and 1.7 kb), presumably by differential usage of poly(A)+ signals. A sequence from -175 to -155 was identified to be an IFN response region that conferred IFN-gamma induction upon a heterologous promoter in lymphoid cell line EL4. This region includes a motif, TTCNNGGAA, designated the palindromic IFN response element (pIRE), to which an IFN-gamma-inducible, cycloheximide-sensitive factor(s) binds. A similar palindromic motif was found in the upstream region of the murine IRF-1 gene, the IFN-gamma activation site of the guanylate-binding protein gene and the IFN-gamma-responsive region of the Fc receptor type I gene, all of which competed with the pIRE for factor binding in gel mobility shift assays. We show that the pIRE binding factor reacts with the antibody against the 91-kDa subunit of ISGF3 alpha recently shown to bind to the IFN-gamma activation site. These results suggest that this factor is related to the IFN-gamma activation factor and contains the 91-kDa subunit of ISGF3 alpha. Taken together, pIRE represents an IRE that is distinct from the classical IFN-stimulated response element and that is capable of conferring IFN-gamma induction through the binding of the 91-kDa ISGF3 alpha subunit (or an antigenically similar molecule).

Interferon-gamma priming effects in the activation and deactivation of ISGF3 in K562 cells.

ISGF3 is a major protein factor which mediates the transcriptional activation of interferon-inducible genes. ISGF3 is composed of two subunits, ISGF3 gamma and ISGF3 alpha, which are stimulated by interferon-gamma (IFN-gamma) and interferon-alpha (IFN-alpha), respectively. In this paper, the effect of pretreatment of IFN-gamma on the response of K562 cells to IFN-alpha, termed "gamma-priming," is examined. Using techniques of gene transfection and mobility shift assay, we studied the gamma-priming effects on the kinetics of appearance and disappearance of (i) the protein product of a luciferase reporter gene driven by an IFN-inducible promoter and (ii) the binding of ISGF3 to the interferon-stimulated response element. We found that exposure of cells to IFN-gamma prior to IFN-alpha greatly increased both the levels and the rate of ISGF3 binding activity during the early phase of IFN-alpha treatment and caused the amount of ISGF3 bound to the interferon-stimulated response element to decrease more rapidly with time during the later phase. Such effects were reflected also on the kinetics of expression of the interferon-inducible luciferase gene induced by IFN-alpha. In order to understand the basis of these gamma-priming effects, we use an in vitro reconstitution method to examine the kinetics of the subcomponents of ISGF3 in response to different IFN treatments in K562 cells. It was found that gamma-priming not only increased the levels of ISGF3 gamma, but it also stimulated both the rates of rise and fall of the activated alpha-component of ISGF3. A molecular model is proposed to explain these findings.

In vitro activation of the transcription factor ISGF3 by interferon alpha involves a membrane-associated tyrosine phosphatase and tyrosine kinase.

Interaction of interferon alpha (IFN alpha) with its cell surface receptor rapidly activates the formation of the transcription complex ISGF3, which subsequently translocates to the nucleus and stimulates the expression of a variety of early response genes. We have recently developed a cell-free system where IFN alpha can activate the formation of ISGF3 in vitro. This system has enabled us to demonstrate that the component of the ISGF3 transcription complex which is modified by IFN alpha treatment (ISGF3 alpha) is membrane-associated and that its activation involves a protein kinase. Using a combination of specific tyrosine kinase and phosphatase inhibitors and monoclonal anti-phosphotyrosine antibodies we now are able to demonstrate that IFN alpha-activated transcription involves at least a two-step process where a membrane-associated tyrosine phosphatase and a tyrosine kinase lead to modification of ISGF3 alpha and subsequent formation of the complete complex. Furthermore, formation of the ISGF3 complex is specifically disrupted by protein tyrosine phosphatase and can be reversibly dissociated by the phosphotyrosine analogue phenylphosphate. The latter observation suggested that SH2 and/or SH3 domains may be required for the stable formation of this transcription complex.

Two domains of ISGF3 gamma that mediate protein-DNA and protein-protein interactions during transcription factor assembly contribute to DNA-binding specificity.

Alpha interferon (IFN-alpha) induces the transcription of a large set of genes through activation of multimeric transcription factor ISGF3. This factor can be dissociated into two protein components, termed ISGF3 gamma and ISGF3 alpha. ISGF3 gamma is a 48-kDa protein related at the amino terminus to members of the IFN-regulatory factor (IRF) and Myb families of DNA-binding proteins; ISGF3 alpha consists of three polypeptides of 84, 91, and 113 kDa that self-assemble to form an activated component in response to IFN-alpha. DNA-binding studies indicated that ISGF3 gamma binds DNA alone, recognizing the IFN-stimulated response element, while the ISGF3 alpha polypeptides alone display no specific interactions with DNA. A complex between ISGF3 gamma and activated ISGF3 alpha binds the IFN-stimulated response element with much greater affinity than does the 48-kDa ISGF3 gamma protein alone. The DNA-binding domain of ISGF3 gamma and regions responsible for protein-protein interaction with ISGF3 alpha were identified by using deleted forms of ISGF3 gamma expressed in vitro. The amino-terminal region of ISGF3 gamma homologous to the IRF and Myb proteins was sufficient for interaction with DNA and displayed the binding specificity of the intact protein; phosphorylation of this region was necessary for activity. A second region of 160 amino acids separated from the DNA-binding domain by over 100 amino acids contained a domain capable of associating with ISGF3 alpha and was sufficient to confer specific ISGF3 alpha interaction to a heterologous protein. Interaction of the ISGF3 alpha component with the protein interaction domain of ISGF3 gamma altered the DNA-binding specificity of the resulting complex, suggesting that one or more of the ISGF3 alpha polypeptides make base-specific contacts with DNA. This interaction defines a mechanism through which IRF-like proteins complexed with regulatory components can display novel DNA-binding specificities.

Interferon-alpha-induced gene expression: evidence for a selective effect of ouabain on activation of the ISGF3 transcription complex.

Binding of interferons (IFNs) to their cell surface receptors stimulates rapid translocation of cytoplasmic proteins to the nucleus and the expression of a variety of cellular genes within minutes. Translocated proteins subsequently bind to the interferon-stimulated response element (ISRE) located in the promoters of all IFN-activated cellular genes. We report here that ouabain, a specific inhibitor of the Na/K ATPase, selectively inhibited transcription of several IFN-alpha-induced cellular RNAs under conditions in which some other well-described signal transduction pathways remained intact. The latter included induction of human metallothionein 2A (HMT2A) by phorbol ester and induction of IP-10 RNA by IFN-gamma. Ouabain itself induced RNA of the protooncogene c-fos which conversely was inhibited by IFN-alpha. Specificity of the ouabain effects on IFN alpha-induced RNAs with respect to a direct action on the Na/K ATPase was shown with a transfected monkey CV-1 cell line which expresses the ouabain-insensitive rat alpha 1 subunit. Electrophoretic mobility shift assays (EMSAs) using nuclear extracts from ouabain-treated cells demonstrated that ouabain decreased IFN alpha-induced binding of the ISGF3 complex to the ISRE. Reconstitution experiments showed that this effect of ouabain is not due to the inhibition of IFN alpha activation of the ISGF3 alpha subcomponent, which occurs in the cytoplasm, but a selective depletion of the ISGF3 gamma factor which in concert with activated ISGF3 alpha induces interferon-stimulated gene (54 kDa) transcription. These findings imply that intracellular ion balance can selectively regulate the half-life of the ISGF3 gamma protein or the ability of this protein to complex with ISGF3 alpha to activate IFN alpha-regulated cellular genes.

Subunit of an alpha-interferon-responsive transcription factor is related to interferon regulatory factor and Myb families of DNA-binding proteins.

Alpha interferon stimulates transcription by converting the positive transcriptional regulator ISGF3 from a latent to an active form. This receptor-mediated event occurs in the cytoplasm, with subsequent translocation of the activated factor to the nucleus. ISGF3 has two components, termed ISGF3 alpha and ISGF3 gamma. ISGF3 gamma serves as the DNA recognition subunit, while ISGF3 alpha, which appears to consist of three polypeptides, is a target for alpha interferon signaling and serves as a regulatory component whose activation is required to form ISGF3. ISGF3 gamma DNA-binding activity was identified as a 48-kDa polypeptide, and partial amino acid sequence has allowed isolation of cDNA clones. ISGF3 gamma translated in vitro from recombinant clones bound DNA with a specificity indistinguishable from that of ISGF3 gamma purified from HeLa cells. Sequencing of ISGF3 gamma cDNA clones revealed significant similarity to the interferon regulatory factor (IRF) family of DNA binding proteins in the amino-terminal 117 residues of ISGF3 gamma. The other IRF family proteins bind DNA with a specificity related to but distinct from that of ISGF3 gamma. We note sequence similarities between the related regions of IRF family proteins and the imperfect tryptophan repeats which constitute the DNA-binding domain of the c-myb oncoprotein. These sequence similarities suggest that ISGF3 gamma and IRF proteins and the c-myb oncoprotein use a common structural motif for DNA recognition. Recombinant ISGF3 gamma, like the natural protein, interacted with HeLa cell ISGF3 alpha to form the mature ISGF3 DNA-binding complex. We suggest that other IRF family members may participate in signaling pathways by interacting with as yet unidentified regulatory subunits analogous to ISGF3 alpha.

Interferon-dependent tyrosine phosphorylation of a latent cytoplasmic transcription factor.

The interferon-alpha (IFN-alpha)-stimulated gene factor 3 (ISGF3), a transcriptional activator, contains three proteins, termed ISGF3 alpha proteins, that reside in the cell cytoplasm until they are activated in response to IFN-alpha. Treatment of cells with IFN-alpha caused these three proteins to be phosphorylated on tyrosine and to translocate to the cell nucleus where they stimulate transcription through binding to IFN-alpha-stimulated response elements in DNA. IFN-gamma, which activates transcription through a different receptor and different DNA binding sites, also caused tyrosine phosphorylation of one of these proteins. The ISGF3 alpha proteins may be substrates for one or more kinases activated by ligand binding to the cell surface and may link occupation of a specific polypeptide receptor with activation of transcription of a set of specific genes.

Interferon-gamma potentiates the antiviral activity and the expression of interferon-stimulated genes induced by interferon-alpha in U937 cells.

Binding of type I interferon (IFN-alpha/beta) to specific receptors results in the rapid transcriptional activation, independent of protein synthesis, of IFN-alpha-stimulated genes (ISGs) in human fibroblasts and HeLa and Daudi cell lines. The binding of ISGF3 (IFN-stimulated gene factor 3) to the conserved IFN-stimulated response element (ISRE) results in transcriptional activation. This factor is composed of a DNA-binding protein (ISGF3 gamma), which normally is present in the cytoplasm, and other IFN-alpha-activated proteins which preexist as latent cytoplasmic precursors (ISGF3 alpha). We have found that ISG expression in the monocytic U937 cell line differs from most cell lines previously examined. U937 cells express both type I and type II IFN receptors, but only IFN-alpha is capable of inducing antiviral protection in these cells. Pretreatment with IFN-gamma potentiates the IFN-alpha-induced protection, but IFN-gamma alone does not have any antiviral activity. ISG15 mRNA accumulation in U937 cells is not detectable before 6 h of IFN-alpha treatment, peaks at 24 h, and requires protein synthesis. Although IFN-gamma alone does not induce ISG expression, IFN-gamma pretreatment markedly increases and hastens ISG expression and transcriptional induction. Nuclear extracts assayed for the presence of ISRE binding factors by electrophoretic mobility shift assays show that ISGF3 is induced by IFN-alpha within 6 h from undetectable basal levels in untreated U937 cells. Activation of ISGF3 alpha, the latent component of ISGF3, occurs rapidly. However, the increase in ISGF3 activity ultimately correlates with the accumulation of ISGF3 gamma induced by IFN-alpha or IFN-gamma.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of protein phosphorylation in activation of interferon-stimulated gene factors.

Possible involvement of protein phosphorylation in interferon (IFN)-mediated activation of IFN-stimulated gene factor 3 (ISGF3) was investigated. For this purpose, in vivo experiments with specific inhibitors of protein kinases and in vitro experiments with protein phosphatases were carried out. In HeLaM cells, 2-aminopurine, an inhibitor of double-stranded RNA-dependent protein kinase, blocked the induction of ISGF3 gamma subunit but not the activation of ISGF3 alpha subunit. A series of experiments using combinations of protein and RNA synthesis inhibitors and 2-aminopurine indicated that the block elicited by 2-aminopurine was at the level of ISGF3 gamma mRNA synthesis. Activation of ISGF3 alpha, although insensitive to 2-aminopurine, was completely blocked by 10 nM staurosporine, an inhibitor of protein kinase C. On the other hand, even 500 nM staurosporine did not block the induction of ISGF3 gamma. Incubation of cytoplasmic or nuclear extracts of IFN-treated HeLaM cells in vitro with alkaline phosphatase completely eliminated their ability to form the ISGF3 complex but not the ISGF1 complex. Treatment with acid phosphatase, on the other hand, changed the electrophoretic mobility of the ISGF3 complex but did not obliterate it. Complementation experiments revealed that ISGF3 alpha was the alkaline phosphatase-sensitive component of the complex. These results suggest that a protein kinase C-mediated phosphorylation step is involved in ISGF3 alpha activation and a 2-aminopurine-sensitive component is involved in ISGF3 gamma mRNA induction.

Protein kinase activity required for an early step in interferon-alpha signaling.

Interferon-alpha (IFN alpha) induces an immediate transcriptional response of a restricted set of genes in target cells. Specific transcription is mediated by the cytoplasmic activation of a transcription factor complex termed ISGF3. ISGF3 is a multimeric protein complex composed of a regulatory component (ISGF3 alpha), which is activated following IFN alpha treatment, and a DNA-binding component (ISGF3 gamma), which recognizes the IFN alpha-stimulated response element (ISRE). Following activation, ISGF3 alpha translocates to the nucleus where ISGF3 assembles as a high affinity complex on the ISRE. The biochemical basis for receptor-mediated activation of ISGF3 is unknown. We report that two potent protein kinase inhibitors, staurosporine and K-252a, ablated the transcriptional response to IFN alpha treatment. These inhibitors prevented the activation of the ISGF3 alpha component without affecting the ISGF3 gamma component, resulting in no accumulation of mature ISGF3 in nuclei of treated cells. Although these agents are potent inhibitors of protein kinase C (PKC), PKC does not mediate ISGF3 alpha activation. Down-regulation of PKC by chronic exposure of cells to 12-O-tetradecanoylphorbol-13-acetate, which led to complete loss of PKC-immunoreactive material, failed to ablate the transcriptional response to IFN alpha or the activation of ISGF3 alpha. The PKC-specific inhibitor calphostin C did not perturb activation or nuclear accumulation of ISGF3. We conclude that a novel, staurosporine/K-252a-sensitive kinase is required for ISGF3 activity and may participate in receptor-mediated signal transduction.