Downregulation of IRF-3 levels by ribozyme modulates the profile of IFNA subtypes expressed in infected human cells

The underlying mechanism and therapeutic potential of IFNs in viral-associated cancers

Interferons (IFNs) are a diverse family of cytokines secreted by various cells, including immune cells, fibroblasts, and certain viral-parasitic cells. They are classified into three types and encompass 21 subtypes based on their sources and properties. The regulatory functions of IFNs closely involve cell surface receptors and several signal transduction pathways. Initially investigated for their antiviral properties, IFNs have shown promise in combating cancer-associated viruses, making them a potent therapeutic approach. Most IFNs have been identified for their role in inhibiting cancer; however, they have also demonstrated cancer-promoting effects under specific conditions. These mechanisms primarily rely on immune regulation and cytotoxic effects, significantly impacting cancer progression. Despite widespread use of IFN-based therapies in viral-related cancers, ongoing research aims to develop more effective treatments. This review synthesizes the signal transduction pathways and regulatory capabilities of IFNs, highlighting their connections with viruses, cancers, and emerging clinical treatments.

Tissue-specific interferon alpha subtype response to SIV infection in brain, spleen, and lung

Interferon alpha (IFNalpha) is a type I interferon that plays a major role in host defense. There are 13 different IFNalpha genes in humans, but much of the work concerning their role in viral defense has been limited to studying either subtype 2 or pan IFNalpha due to the inability to distinguish between highly similar genetic and amino acid sequences. Because of recent advances in molecular and biochemical techniques, it is possible to study the regulation of individual subtypes. It has been reported that HIV/SIV infection results in impaired IFNalpha responses in certain tissues. Using a pigtailed macaque SIV model, we examined the subtype response during acute infection in 3 tissues that are known to be infected with HIV/SIV, but whose IFNalpha subtype response has not been extensively studied: the brain, spleen, and lung. We found that the expression and regulation of specific subtypes occur in a tissue-specific manner. There was more limited IFNalpha subtype expression in the lung and brain, where predominantly macrophages are infected compared to the spleen, which contains both infected CD4+ lymphocytes and macrophages. Understanding the IFNalpha subtype response in tissues known to be infected with HIV/SIV can help tailor adjunctive treatment regimens to highly active antiretroviral therapy.

Hyperglycemia, oxidative and nitrosative stress affect antiviral, inflammatory and apoptotic signaling of cultured thymocytes

A high prevalence of various infectious diseases is reported in diabetic patients, which may suggest impaired innate immunity against different pathogen-associated molecular patterns. This study investigated the effects of hyperglycemia, oxidative stress (H(2)O(2)), nitric oxide (NO) and peroxynitrite (ONOO(-)) on the modulation of antiviral (MDA-5, IRF-3 and phospho-IRF-3), inflammatory (NF-kappaB) and pro/anti-apoptotic molecules (Bax and Bcl-2) in BALB/c mice thymocytes. Each of the experimental conditions, except the weakest NO concentration, resulted in down-regulation of MDA-5, IRF-3 and phospho-IRF-3. In contrast, each of the experimental conditions elicited up-regulation of NF-kappaB, Bcl-2 and Bax. These results suggest that hyperglycemia, oxidative and nitrosative stress may contribute to the reduced immunity of the host by altering the MDA-5/IRF-3/phosphoIRF-3 axis, as well as contributing to the mechanisms of inflammatory reaction via increased NF-kappaB, and to augmented turnover rate of thymocyte cells via Bcl2/Bax up-regulation.

Role of interferon in the replication of human parainfluenza virus type 1 wild type and mutant viruses in human ciliated airway epithelium

Human parainfluenza virus type 1 (HPIV1) is a significant cause of pediatric respiratory disease in the upper and lower airways. An in vitro model of human ciliated airway epithelium (HAE), a useful tool for studying respiratory virus-host interactions, was used in this study to show that HPIV1 selectively infects ciliated cells within the HAE and that progeny virus is released from the apical surface with little apparent gross cytopathology. In HAE, type I interferon (IFN) is induced following infection with an HPIV1 mutant expressing defective C proteins with an F170S amino acid substitution, rHPIV1-C(F170S), but not following infection with wild-type HPIV1. IFN induction coincided with a 100- to 1,000-fold reduction in virus titer, supporting the hypothesis that the HPIV1 C proteins are critical for the inhibition of the innate immune response. Two recently characterized live attenuated HPIV1 vaccine candidates expressing mutant C proteins were also evaluated in HAE. The vaccine candidates, rHPIV1-C(R84G/Delta170)HN(T553A)L(Y942A) and rHPIV1-C(R84G/Delta170)HN(T553A)L(Delta1710-11), which contain temperature-sensitive (ts) attenuating (att) and non-ts att mutations, were highly restricted in growth in HAE at permissive (32 degrees C) and restrictive (37 degrees C) temperatures. The viruses grew slightly better at 37 degrees C than at 32 degrees C, and rHPIV1-C(R84G/Delta170)HN(T553A)L(Y942A) was less attenuated than rHPIV1-C(R84G/Delta170)HN(T553A)L(Delta1710-11). The level of replication in HAE correlated with that previously observed for African green monkeys, suggesting that the HAE model has potential as a tool for the preclinical evaluation of HPIV1 vaccines, although how these in vitro data will correlate with vaccine virus replication in seronegative human subjects remains to be seen.

Recruitment of activated IRF-3 and CBP/p300 to herpes simplex virus ICP0 nuclear foci: Potential role in blocking IFN-beta induction

The host innate response to viral infection includes the production of interferons, which is dependent on the coordinated activity of multiple transcription factors. Herpes simplex virus 1 (HSV-1) has been shown to block efficient interferon expression by multiple mechanisms. We and others have demonstrated that HSV-1 can inhibit the transcription of genes promoted by interferon regulatory factor-3 (IRF-3), including interferon beta (IFN-beta), and that the immediate-early ICP0 protein is sufficient for this function. However, the exact mechanism by which ICP0 blocks IRF-3 activity has yet to be determined. Unlike some other viral proteins that inhibit IRF-3 activity, ICP0 does not appear to affect phosphorylation and dimerization of IRF-3. Here, we show that a portion of activated IRF-3 co-localizes with nuclear foci containing ICP0 at early times after virus infection. Co-localization to ICP0-containing foci is also seen with the IRF-3-binding partners and transcriptional co-activators, CBP and p300. In addition, using immunoprecipitation of infected cell lysates, we can immunoprecipitate a complex containing ICP0, IRF-3, and CBP. Thus we hypothesize that ICP0 recruits activated IRF-3 and CBP/p300 to nuclear structures, away from the host chromatin. This leads to the inactivation and accelerated degradation of IRF-3, resulting in reduced transcription of IFN-beta and an inhibition of the host response. Therefore, ICP0 provides an example of how viruses can block IFN-beta induction by sequestration of important transcription factors essential for the host response.

Attenuating mutations in the P/C gene of human parainfluenza virus type 1 (HPIV1) vaccine candidates abrogate the inhibition of both induction and signaling of type I interferon (IFN) by wild-type HPIV1

Recombinant human parainfluenza virus type 1 (HPIV1) and mutants containing point and deletion (Delta) mutations in the P/C gene (r-CDelta10-15HNT553A, r-CR84G, r-CF170S and r-CDelta170), which have previously been evaluated as HPIV1 vaccine candidates, were evaluated for their effect on the type I interferon (IFN) response in vitro. HPIV1 wt infection inhibited the IFN response by inhibiting IFN regulatory factor-3 (IRF-3) activation and IFN production in A549 cells and IFN signaling in Vero cells. In contrast, r-CR84G, r-CF170S and r-CDelta170 were defective for inhibition of IRF-3 activation and IFN production and r-CF170S and r-CDelta170 did not inhibit IFN signaling. Thus, HPIV1 antagonizes the IFN response at both the level of induction and signaling, and antagonism at both levels was disrupted by mutations in the P/C gene. Because CF170S affects C and not P, the anti-IFN function can be attributed to the C proteins. These data, in the context of previous in vivo studies, suggest that the loss of antagonism of the IFN response at both the level of induction and signaling, observed with the P/C mutants, r-CF170S and r-CDelta170, was necessary for significant attenuation in African green monkeys (AGMs).

Convergence of the NF-κB and Interferon Signaling Pathways in the Regulation of Antiviral Defense and Apoptosis

The ubiquitously expressed interferon regulatory factor 3 (IRF-3) is directly activated following virus infection and functions as a key activator of the immediate-early Type 1 interferon (IFN) genes. Using DNA microarray analysis (8,556 genes) in Jurkat T cells inducibly expressing constitutively active IRF-3, several target genes directly regulated by IRF-3 were identified. Among the genes upregulated by IRF-3 were transcripts for a subset of known IFN-stimulated genes (ISGs), including ISG56, which functions as an inhibitor of translation initiation. Phosphorylation of C-terminal Ser/Thr residues--(382)GGASSLENTVDLHISNSHPLSLTSDQY(408)-is required for IRF-3 activation. Using C-terminal point mutations and a novel phosphospecific antibody, Ser396 was characterized as the minimal phosphoacceptor site required in vivo for IRF-3 activation following Sendai virus (SeV) infection, expression of viral nucleocapsid, or double-stranded RNA (dsRNA) treatment. The identity of the virus-activated kinase (VAK) activity that targets and activates IRF-3 and IRF-7 has remained a critical missing link in the understanding of interferon signaling. We report that the IKK-related kinases-IKKepsilon/TBK-1-are components of VAK that mediate IRF-3 and IRF-7 phosphorylation and thus functionally link the NF-kappaB and IRF pathways in the development of the antiviral response.

A novel chimeric ribozyme vector produces potent inhibition of ICAM-1 expression on ischemic vascular endothelium

BACKGROUND

Inhibition of intercellular adhesion molecule-1 (ICAM-1) expression can ameliorate the inflammation induced by ischemia-reperfusion injury (IRI) in animal models. However, current strategies to reduce ICAM-1 expression have been limited by the lack of stability, poor specificity, and the transient nature of synthesized regulatory molecules (antisense/ribozyme).

METHODS

A chimeric expression vector was generated by fusing a ribozyme targeting sequence against ICAM-1 to stabilizing stem-loop structures and nuclear localization signals that are components of endogenous U1 small nuclear RNA. Oligonucleotide scanning was used to predict accessible sites for targeting within the rat ICAM-1 transcript. Efficacy of the chimeric ribozyme vector was tested by transfection of rat aortic endothelial (RAE) cells (in vitro) and intraportal delivery in a rat hepatic IRI model (in vivo).

RESULTS

Transfection of RAE cells with the chimeric ribozyme vector produced potent and specific inhibition of ICAM-1 mRNA and protein levels by >65%. This reduction in ICAM-1 expression was accompanied by a proportional decrease in neutrophil adhesion to RAE cells. In vivo intraportal delivery of the chimeric targeting vector to rats sustaining hepatic IRI produced a marked reduction in ICAM-1 expression on liver endothelium after reperfusion.

CONCLUSIONS

A chimeric ribozyme vector effectively inhibited ICAM-1 expression in vascular endothelial cells and in rat liver following IRI, demonstrating a novel gene targeting technique that may be ideally suited to clinical applications aimed at ameliorating IRI.

Herpes simplex virus 1 has multiple mechanisms for blocking virus-induced interferon production

In response to viral infection, host cells elicit a number of responses, including the expression of alpha/beta interferon (IFN-alpha/beta). In these cells, IFN regulatory factor-3 (IRF-3) undergoes a sequence of posttranslational modifications that allow it to act as a potent transcriptional coactivator of specific IFN genes, including IFN-beta. We investigated the mechanisms by which herpes simplex virus 1 (HSV-1) inhibits the production of IFN-beta mediated by the IRF-3 signaling pathway. Here, we show that HSV-1 infection can block the accumulation of IFN-beta triggered by Sendai virus (SeV) infection. Our results indicate that HSV-1 infection blocks the nuclear accumulation of activated IRF-3 but does not block the initial virus-induced phosphorylation of IRF-3. The former effect was at least partly mediated by increased turnover of IRF-3 in HSV-1-infected cells. Using mutant viruses, we determined that the immediate-early protein ICP0 was necessary for the inhibition of IRF-3 nuclear accumulation. Expression of ICP0 also had the ability to reduce IFN-beta production induced by SeV infection. ICP0 has been shown previously to play a role in HSV-1 sensitivity to IFN and in the inhibition of antiviral gene production. However, we observed that an ICP0 mutant virus still retained the ability to inhibit the production of IFN-beta. These results argue that HSV-1 has multiple mechanisms to inhibit the production of IFN-beta, providing additional ways in which HSV-1 can block the IFN-mediated host response.

Kaposi's sarcoma-associated herpesvirus-encoded vIRF-3 stimulates the transcriptional activity of cellular IRF-3 and IRF-7

Kaposi's sarcoma-associated herpesvirus has been linked to Kaposi's sarcoma, body cavity-based lymphoma, and Castleman's disease. The Kaposi's sarcoma-associated herpesvirus genome contains a cluster of open reading frames encoding proteins (vIRFs) with homology to the cellular transcription factors of the interferon regulatory factor family. vIRF-3, also called LANA2, is a latently expressed nuclear protein. Here we demonstrate that vIRF-3 directly interacts with cellular interferon regulatory factor (IRF) IRF-3, IRF-7, and the transcriptional co-activator CBP/p300. The mapping of the vIRF-3 binding domain revealed that vIRF-3 associates with both IRF-3 and IRF-7 through its C-terminal region. The p300 domain, which interacts with vIRF-3, is distinct from the previously identified IBiD domain, to which both vIRF-1 and IRF-3 bind. Thus, in contrast to vIRF-1, vIRF-3 neither blocks the interaction between IRF-3 and p300 nor inhibits the histone acetylation. Although vIRF-3 is not a DNA-binding protein, it is recruited to the IFNA promoters via its interaction with IRF-3 and IRF-7. The presence of vIRF-3 in the enhanceosome assembled on the IFNA promoters increases binding of IRF-3, IRF-7, and acetylated histone H3 to this promoter region. Consequently, vIRF-3 stimulates the IRF-3- and IRF-7-mediated activation of type I interferon (IFNA and IFNB) genes and the synthesis of biologically active type I interferons in infected B cells. These studies illustrate that vIRF-3 and vIRF-1 have clearly distinct functions. In addition to its co-repressor activity, vIRF-3 can also act as a transcriptional activator on genes controlled by cellular IRF-3 and IRF-7.

Sendai virus targets inflammatory responses, as well as the interferon-induced antiviral state, in a multifaceted manner

We have used cDNA arrays to compare the activation of various cellular genes in response to infection with Sendai viruses (SeV) that contain specific mutations. Three groups of cellular genes activated by mutant SeV infection, but not by wild-type SeV, were identified in this way. While some of these genes are well known interferon (IFN)-stimulated genes, others, such as those for interleukin-6 (IL-6) and IL-8, are not directly induced by IFN. The gene for beta IFN (IFN-beta), which is critical for initiating an antiviral response, was also specifically activated in mutant SeV infections. The SeV-induced activation of IFN-beta was found to depend on IFN regulatory factor 3, and the activation of all three cellular genes was independent of IFN signaling. Mutations that disrupt four distinct elements in the SeV genome (the leader RNA, two regions of the C protein, and the V protein) all lead to enhanced levels of IFN-beta mRNA, and at least three of these viral genes also appear to be involved in preventing activation of IL-8. Our results suggest that SeV targets the inflammatory and adaptive immune responses as well as the IFN-induced intracellular antiviral state by using a multifaceted approach.

Virus-induced heterodimer formation between IRF-5 and IRF-7 modulates assembly of the IFNA enhanceosome in vivo and transcriptional activity of IFNA genes

Transcription factors of the interferon regulatory factor (IRF) family have been identified as critical mediators of early inflammatory gene transcription in infected cells. We have shown previously that IRF-5, like IRF-3 and IRF-7, is a direct transducer of virus-mediated signaling and plays a role in the expression of multiple cytokines/chemokines. The present study is focused on the molecular mechanisms underlying the formation and function of IRF-5/IRF-7 heterodimers in infected cells. The interaction between IRF-5 and IRF-7 is not cooperative and results in a repression rather than enhancement of IFNA gene transcription. The formation of the IRF-5/IRF-7 heterodimer is dependent on IRF-7 phosphorylation, as shown by the glutathione S-transferase pull-down and immunoprecipitation assays. Mapping of the interaction domain revealed that formation of IRF-5/IRF-7 heterodimers occurs through the amino terminus resulting in a masking of the DNA binding domain, the consequent alteration of the composition of the enhanceosome complex binding to IFNA promoters in vivo, and modulation of the expression profile of IFNA subtypes. Thus, these results indicate that IRF-5 can act as both an activator and a repressor of IFN gene induction dependent on the IRF-interacting partner, and IRF-5 may be a part of the regulatory network that ensures timely expression of the immediate early inflammatory genes.

Differential expression of IFN-alpha subtypes in human PBMC: evaluation of novel real-time PCR assays

Studies of the human IFN-alpha subtype system have been hampered by the lack of efficient procedures to quantify and differentiate the expression of the highly homologous IFN-alpha subtypes. Here we evaluate four novel real-time PCR assays for the specific detection and quantification of IFN-alpha mRNA for the subtypes alpha(2), alpha(6), alpha(8) and alpha(1/13) in a combined assay in human peripheral blood mononuclear cells (PBMC). This included (a) the selection of beta-glucuronidase (GUS) as a suitable housekeeping gene for relative quantification; (b) verification of the specificity by using human DNA of different IFN-alpha subtypes; and (c) comparison of the amplification efficiencies among the different assays. This highly sensitive method allows the detection of low-level, constitutive IFN-alpha mRNA and shows differences in the composition of constitutive IFN-alpha subtypes compared to other cell types (HeLa and HEp-2). The in vitro stimulation of PBMC with Newcastle disease virus (NDV), Respiratory syncytial virus (RSV) or an inactivated Herpes simplex (HSV) preparation leads to the transcriptional induction of all IFN-alpha subtypes investigated but to different expression levels. Among the subtypes detected, IFN-alpha(13/1) and alpha(2) are the major transcripts followed by alpha(8), and finally alpha(6) as a minor transcribed subtype. Time-kinetics of IFN-alpha transcriptional activation also revealed variations in the course of IFN-alpha transcription between NDV, RSV or HSV. The data obtained from the real-time PCR assays correlated well with IFN-alpha(2) protein release. In conclusion, we have demonstrated the suitability and reliability of new real-time PCR assays for the rapid and efficient analysis of IFN-alpha subtype expression.

Multiple regulatory domains of IRF-5 control activation, cellular localization, and induction of chemokines that mediate recruitment of T lymphocytes

Transcription factors of the interferon regulatory factor (IRF) family have been identified as critical mediators of early inflammatory gene transcription in infected cells. We recently determined that, besides IRF-3 and IRF-7, IRF-5 serves as a direct transducer of virus-mediated signaling. In contrast to that mediated by the other two IRFs, IRF-5-mediated activation is virus specific. We show that, in addition to Newcastle disease virus (NDV) infection, vesicular stomatitis virus (VSV) and herpes simplex virus type 1 (HSV-1) infection activates IRF-5, leading to the induction of IFNA gene subtypes that are distinct from subtypes induced by NDV. The IRF-5-mediated stimulation of inflammatory genes is not limited to IFNA since in BJAB/IRF-5-expressing cells IRF-5 stimulates transcription of RANTES, macrophage inflammatory protein 1 beta, monocyte chemotactic protein 1, interleukin-8, and I-309 genes in a virus-specific manner. By transient- transfection assay, we identified constitutive-activation (amino acids [aa] 410 to 489) and autoinhibitory (aa 490 to 539) domains in the IRF-5 polypeptide. We identified functional nuclear localization signals (NLS) in the amino and carboxyl termini of IRF-5 and showed that both of these NLS are sufficient for nuclear translocation and retention in infected cells. Furthermore, we demonstrated that serine residues 477 and 480 play critical roles in the response to NDV infection. Mutation of these residues from serine to alanine dramatically decreased phosphorylation and resulted in a substantial loss of IRF-5 transactivation in infected cells. Thus, this study defines the regulatory phosphorylation sites that control the activity of IRF-5 in NDV-infected cells and provides further insight into the structure and function of IRF-5. It also shows that the range of IRF-5 immunoregulatory target genes includes members of the cytokine and chemokine superfamilies.

Regulation of virus-induced interferon-A genes

Different members of the interferon regulatory factor (IRF) family are early activated by viral infection of eukaryotic cells. The IRFs participate in the virus-induced transcriptional regulation of different genes, including the multigenic interferon-A (IFN-A) family, members of which are involved in the establishment of an antiviral state, cell growth inhibition or apoptosis. This study presents the recent progress in the field of virus-induced transactivation and repression of IFN-A gene promoters. Data presented on the modular organization of IFN-A gene promoters and their transactivation dependent on IRF-3 and IRF-7 provide a new insight on the cooperativity mechanisms among the different IRF family members. Data on the transcriptional repression of virus-induced interferon-A promoters by the homeodomain protein Pitx1 contribute to our understanding of the complex differential transcriptional activation, repression and antirepression of the IFN-A genes.

Viruses and the type I interferon antiviral system: induction and evasion

The type I interferon (IFN) system responds to viral infection and induces an "antiviral state" in cells, providing an important first line of defense against virus infection. Interaction of type I IFNs (IFN alpha and IFN beta) with their receptor induces hundreds of cellular genes. Of the proteins induced by IFN, the antiviral function of only a few is known, and their mechanisms of action are only partly understood. Additionally, although viral-encoded mechanisms that counteract specific components of the type I IFN response have been known for some time, it has recently become clear that many (if not most) viruses encode some form of IFN-antagonist. Understanding the interplay between viral-encoded IFN antagonists and the interferon response will be essential if the therapeutic potential of IFNs is to be fully exploited.

Direct involvement of CREB-binding protein/p300 in sequence-specific DNA binding of virus-activated interferon regulatory factor-3 holocomplex

Infections of bacteria and viruses induce host defense reactions known as innate responses including the activation of interferon regulatory factor-3 (IRF-3), critical for the activation of type I interferon system. Upon immediate early signals triggered by the infection, IRF-3 is phosphorylated and a homodimer results. The homodimer complexes with the coactivator CREB-binding protein (CBP)/p300 in the nucleus; thus, holocomplex of IRF-3 competent in DNA binding is generated. We showed CBP/p300 to be indispensable for the DNA binding activity of the holocomplex and to aid the binding through direct interaction with the DNA. We demonstrated that p300 binds with the IRF-3 homodimer via a Q-rich domain and that an intact histone acetyltransferase (HAT) domain is indispensable for the DNA binding of the holocomplex along with a CH3 domain, which connects the HAT and Q-rich domains. These results highlight a novel function of CBP/p300: direct involvement in sequence-specific DNA binding. Furthermore, the critical function of these domains in virus-induced gene activation was demonstrated in vivo by using p300 mutants.

The interferon antiviral response: from viral invasion to evasion

One of the initial responses of an organism to infection by pathogenic viruses is the synthesis of antiviral cytokines such as the type I interferons (interferon-alpha/beta), interleukins, and other proinflammatory cytokines and chemokines. Interferons provide a first line of defence against virus infections by generating an intracellular environment that restricts virus replication and signals the presence of a viral pathogen to the adaptive arm of the immune response. Interferons stimulate cells in the local environment to activate a network of interferon-stimulated genes, which encode proteins that have antiviral, antiproliferative and immunomodulatory activities. The present review focuses on recent reports that describe the activation of multiple signalling pathways following virus infection, new candidate genes that are implicated in the establishment of the antiviral state, and the strategies used by viruses and their specific viral products to antagonize and evade the host antiviral response.

Stimulation of IRF-7 gene expression by tumor necrosis factor alpha: requirement for NFkappa B transcription factor and gene accessibility

Interferon regulatory factor 7 (IRF-7) plays an important role in innate immunity, where, together with IRF-3, it controls the expression of interferon A/B genes as well as chemokine RANTES (regulated on activation normal T cell expressed and secreted). Previously, we characterized human IRF-7 promoter and showed that an interferon-stimulated response element site in the first intron binds interferon-stimulated gene factor 3 (ISGF3) and confers the response to interferon. Here we report the stimulation of IRF-7 expression by 12-O-tetradecanoylphorbol-13-acetate (TPA) and tumor necrosis factor alpha (TNFalpha) in human peripheral blood monocytes. Using promoter analysis in combination with electrophoretic mobility shift assays, we have demonstrated that an NFkappaB site located next to the TATA box, binds p50 and p65 heterodimer and is required for the induction of the IRF-7 gene by TPA and TNFalpha. In addition, we report stimulation of IRF-7 gene expression by topoisomerase II (TOPII) inhibitors. We show by chromatin immunoprecipitation assay that treatment with the TOPII inhibitor etoposide induces association of acetylated histone 3 with the promoter of IRF-7 gene, indicating that TOPII-mediated changes in chromatin structure could be responsible for the induction. This suggests that the IRF-7 gene is localized in the condensed area of the chromosome where it is inaccessible to transcription factors that would promote its constitutive expression.

The virus-induced factor VIF differentially recognizes the virus-responsive modules of the mouse IFNA4 gene promoter

Maximal activation of murine infection-A4 (IFNA4) gene transcription following viral infection requires the presence of four cooperating DNA sequences (denoted A to D), which make up the virus responsive element VRE-A4. The B, C, and D modules, when tandemized, form binding sites for the virus-induced factor (VIF), a multiprotein complex that is detected early after viral infection in the nuclei of mouse L929 cells. We now demonstrate that IFN regulatory factor-3 (IRF-3) is a component of VIF and that VIF is different from the previously identified virus-activated complexes containing IRF-3 and coactivators of transcription, such as CREB binding protein (CBP) or p300. We also show that the C module is critical for both IRF-3-mediated and virus-induced transcription of the murine IFNA4 gene. Consistently, DNase I footprinting experiments and EMSA performed with increasing amounts of recombinant GST-IRF-3(DBD) fusion proteins demonstrate that cooperativity between the modules facilitate the binding of IRF-3 and recruitment of transcription coactivators on the IFNA4 promoter. These results indicate that VIF differentially recognizes the virus-responsive modules of VRE-A4 and further actualize our previous model concerning the differential expression of murine IFNA genes.

Control of IRF-3 activation by phosphorylation

Interferon (IFN) regulatory factor-3 (IRF-3) is a unique member of the IRF family. Its transcriptional activity is regulated solely by posttranslational modifications. We review current knowledge of the mechanism of IRF-3 activation: signalling triggered by infections including viruses and bacteria, phosphorylation of IRF-3 on certain serine residues, homodimer formation, and active holocomplex formation with coactivator CBP/p300.

Enhancement and diversification of IFN induction by IRF-7-mediated positive feedback

Interferons (IFN) are potent components of the innate immune response to microbial infection. The genes for type I IFN (IFN-alpha and IFN-beta) are rapidly induced in response to viral infection through a mechanism that involves latent cellular transcription factors that are activated in response to innate recognition of viral components. IFN regulatory factor (IRF) proteins are key to this regulation, and their conversion from latent to active involves virus-induced serine phosphorylation. Differential utilization of distinct IRF proteins by different members of the type I IFN gene family produces a graded induction of gene expression, resulting in tight control of these cytokines through a positive feedback mechanism. Early response to virus causes secretion of a subset of IFN genes through the action of IRF-3 in conjunction with additional transcription factors, such as NF-kappaB and activator protein-1 (AP-1) (c-jun/ATF). This early IFN acts in an autocrine manner to stimulate production of IRF-7, a transcription factor capable of activating the many additional members of the IFN-alpha gene family. The dependence of IRF-7 on virus-induced phosphorylation for its activity insures that IFN production is limited to virus-infected cells. Characterization of the cellular components involved in viral detection and IRF activation will further delineate this vital mechanism of innate immune response.

On the role of IRF in host defense

Transcription factors of the interferon (IFN) regulatory factor (IRF) family have been shown to play an essential role in the regulated expression of type I IFN genes, IFN-stimulated genes (ISG), and other cytokines and chemokines. Three members of the IRF family, IRF-3, IRF-5, and IRF-7, have been identified as acting as direct transducers of virus-mediated signaling. In infected cells, these factors are activated by phosphorylation on the serine residues, transported to the nucleus, where they bind to the promoters of IFNA and IFNB genes and tether histone transacetylases to the transcription complex enhanceosome. IFNB and IFNA subtypes are expressed at different levels in infected cells. The ratio between the relative levels of IRF-3 and IRF-7 was shown to play an essential role in the inducible expression of type I IFN genes, whereas IRF-3 alone is sufficient for expression of the IFNB gene. IRF-5 was identified recently as another inducer of IFNA genes, which has two unique properties: (1) its activation is virus specific, and (2) the profile of IFNA genes induced by IRF-5 is distinct from that induced by IRF-7. Several viruses target functions of IRF to eliminate the early inflammatory response. Kaposi's sarcoma herpesvirus (KSHV) encodes a cluster of four genes with homology to cellular IRF. Three of these vIRF were shown to inhibit induction of IFN genes and ISG in infected cells and function as dominant negative mutants of cellular IRF. The unique properties of previously uncharacterized vIRF-2 and vIRF-3 are discussed.

Monocyte differentiation to macrophage requires interferon regulatory factor 7

Interferon regulatory factors are a growing family of transcription factor that have been implicated in cellular events such as cell-growth regulation, antiviral defense, and development of the immune system. Interferon regulatory factor 7 (IRF-7) is expressed predominantly in lymphoid tissues and has been studied extensively in the context of viral infection and the induction of interferon and cytokine gene expression. In this paper, the involvement of IRF-7 in monocyte differentiation was examined in U937, HL60, and human primary macrophages. We report the induction of IRF-7 expression by 12-O-tetradecanoylphorbol-13-acetate in U937 and HL60 cells and demonstrate that this induction is essential for the monocyte differentiation to macrophages. We show that the monocyte differentiation is inhibited in cells expressing a dominant negative IRF-7 mutant, as evidenced by decreased expression of two macrophage-differentiation markers, CD11b and CD11c, and impaired phagocytic activity. In addition, we demonstrate that overexpression of IRF-7 is sufficient to trigger monocyte differentiation and to induce cell cycle arrest. The identification of IRF-7 as a key regulator in monocyte differentiation suggests a novel function of IRF-7 in innate immunity.

Recruitment of multiple interferon regulatory factors and histone acetyltransferase to the transcriptionally active interferon a promoters

Type I interferon (IFN) plays a critical role in the innate immunity against viral infection. Expression of IFNA genes in infected cells is cell type-dependent and is regulated at the transcriptional level. The present study is focused on the molecular mechanism underlying the differential expression of human IFNA1 and A2 genes. Two nucleotides, at positions -98 and -81 of IFNA1 and A2 promoter, were pivotal to the differential expression. The DNA pull-down and chromatin precipitation assays have shown that nuclear interferon regulatory factor (IRF)-3 and IRF-7 as well as IRF-1 bind to IFNA1 virus-responsive element (VRE). Interestingly, overexpression of IRF-7 increased the otherwise weak binding of both IRF-3 and IRF-7 to IFNA2 VRE. These data together with the results of two-step chromatin immunoprecipitation strongly suggest that the IRF-3 and IRF-7 bind to IFNA1 promoter as a dimer. Furthermore, binding of IRF-3 and IRF-7 to IFNA VRE is associated with the presence of acetylated histone H3, suggesting that histone acetyltransferase(s) is tethered together with virus-activated IRF-3 and IRF-7 to the IFNA1 promoter. In addition, the constitutively active IRF-3 (5D) and IRF-7 (2D) mutants activate the endogenous IFNA genes in uninfected cells; however, the expression profile of IFNA is not identical to that induced by viral infection.

Virus-specific activation of a novel interferon regulatory factor, IRF-5, results in the induction of distinct interferon alpha genes

Interferon regulatory factor (IRF) genes encode DNA-binding proteins that are involved in the innate immune response to infection. Two of these proteins, IRF-3 and IRF-7, serve as direct transducers of virus-mediated signaling and play critical roles in the induction of type I interferon genes. We have now shown that another factor, IRF-5, participates in the induction of interferon A (IFNA) and IFNB genes and can replace the requirement for IRF-7 in the induction of IFNA genes. We demonstrate that, despite the functional similarity, IRF-5 possesses unique characteristics and does not have a redundant role. Thus, 1) activation of IRF-5 by phosphorylation is virus-specific, and its in vivo association with the IFNA promoter can be detected only in cells infected with NDV, not Sendai virus, while both viruses activate IRF-3 and IRF-7, and 2) NDV infection of IRF-5-overexpressing cells preferentially induced the IFNA8 subtype, while IFNA1 was primarily induced in IRF-7 expressing cells. These data indicate that multiple signaling pathways induced by infection may be differentially recognized by members of the IRF family and modulate transcription of individual IFNA genes in a virus and cell type-specific manner.