Requirement of NOX2 and reactive oxygen species for efficient RIG-I-mediated antiviral response through regulation of MAVS expression.

The innate immune response is essential to the host defense against viruses, through restriction of virus replication and coordination of the adaptive immune response. Induction of antiviral genes is a tightly regulated process initiated mainly through sensing of invading virus nucleic acids in the cytoplasm by RIG-I like helicases, RIG-I or Mda5, which transmit the signal through a common mitochondria-associated adaptor, MAVS. Although major breakthroughs have recently been made, much remains unknown about the mechanisms that translate virus recognition into antiviral genes expression. Beside the reputed detrimental role, reactive oxygen species (ROS) act as modulators of cellular signaling and gene regulation. NADPH oxidase (NOX) enzymes are a main source of deliberate cellular ROS production. Here, we found that NOX2 and ROS are required for the host cell to trigger an efficient RIG-I-mediated IRF-3 activation and downstream antiviral IFNbeta and IFIT1 gene expression. Additionally, we provide evidence that NOX2 is critical for the expression of the central mitochondria-associated adaptor MAVS. Taken together these data reveal a new facet to the regulation of the innate host defense against viruses through the identification of an unrecognized role of NOX2 and ROS.

Dual role of NOX2 in respiratory syncytial virus- and sendai virus-induced activation of NF-kappaB in airway epithelial cells.

Human respiratory syncytial virus (RSV), a member of the Paramyxoviridae family, is the most important viral agent of pediatric respiratory tract disease worldwide. Human airway epithelial cells (AEC) are the primary targets of RSV. AEC are responsible for the secretion of a wide spectrum of cytokines and chemokines that are important mediators of the exacerbated airway inflammation triggered by the host in response to RSV infection. NF-kappaB is a key transcription factor responsible for the regulation of cytokine and chemokine gene expression and thus represents a potential therapeutic target. In the present study, we sought to delineate the role of RSV-induced reactive oxygen species in the regulation of the signaling pathways leading to NF-kappaB activation. First, we demonstrate that besides the well-characterized IkappaBalpha-dependent pathway, phosphorylation of p65 at Ser(536) is an essential event regulating NF-kappaB activation in response to RSV in A549. Using antioxidant and RNA-interference strategies, we show that a NADPH oxidase 2 (NOX2)-containing NADPH oxidase is an essential regulator of RSV-induced NF-kappaB activation. Molecular analyses revealed that NOX2 acts upstream of both the phosphorylation of IkappaBalpha at Ser(32) and of p65 at Ser(536) in A549 and normal human bronchial epithelial cells. Similar results were obtained in the context of infection by Sendai virus, thus demonstrating that the newly identified NOX2-dependent NF-kappaB activation pathway is not restricted to RSV among the Paramyxoviridae. These results illustrate a previously unrecognized dual role of NOX2 in the regulation of NF-kappaB in response to RSV and Sendai virus in human AEC.

Binding of Kaposi's sarcoma-associated herpesvirus K-bZIP to interferon-responsive factor 3 elements modulates antiviral gene expression.

Kaposi's sarcoma-associated herpesvirus encodes numerous regulatory proteins capable of modulating viral and cellular gene expression and affecting host cell functions. K-bZIP, a leucine zipper-containing transcription factor encoded by ORFK8, is one such protein. During infection, transcription of the ORFK8 early gene is turned on by the immediate-early replication and transcription factor activator (RTA). One described function of the K-bZIP nuclear protein is to interact with and repress RTA-mediated transactivation of viral promoters, including that of the K8 gene. In the present work, we provide evidence that the expression of K-bZIP results in the activation of the ifn-beta gene. Of interest, ifn-beta gene activation by K-bZIP is independent of interferon (IFN)-responsive factor 3 (IRF-3) and nuclear factor kappaB (NF-kappaB) activation. Using a DNA binding affinity assay and electromobility shift assay, we report that K-bZIP binds efficiently to the PRDIII-I region of the beta IFN (IFN-beta) promoter, and, in doing so, it prevents the attachment of activated IRF-3 but not that of NF-kappaB or ATF2/c-Jun to the IFN-beta promoter sequence. As a consequence, ifn-beta gene activation in response to IFN inducers such as Sendai virus infection or expression of retinoic acid-inducible gene I, mitochondrial antiviral signaling protein, or TANK-binding kinase 1 (TBK-1) is severely impaired (>90%) by the presence of K-bZIP. K-bZIP also prevents the activation of RANTES and CXCL11, whose promoters are also regulated by IRF-3. Lysine 158 (target for SUMO conjugation), threonine 111, and serine 167 (targets for phosphorylation) mutants of K-bZIP were equally effective as wild-type K-bZIP in mediating the repression of TBK-1-activated ifn-beta gene expression. Lastly, the overexpression of CREB binding protein could not reverse the K-bZIP repression of TBK-1-activated ifn-beta gene expression. In all, our results indicate that K-bZIP binds directly to the PRDIII-I region of the IFN-beta promoter and, as a consequence, causes a low level of ifn-beta gene transcription. In doing so, K-bZIP prevents IRF-3 from binding to the IFN-beta promoter and precludes the formation of the enhanceosome, which is required for maximal ifn-beta gene transcription. A new role for K-bZIP as a protein involved in immune evasion is therefore uncovered.

Innate host defense: Nox and Duox on phox's tail.

Over the past decade, the capacity of non-phagocytic cells to produce superoxide has been largely documented. As in the case of the well-characterized phagocytic cells context, superoxide formation in non-phagocytic cells depends on the activity of membrane bound NADPH oxidase enzymes. Six mammalian homologues of the classical phagocytic Nox2 enzyme have been described to date, named Nox1, Nox3, Nox4, Nox5, Duox1 and Duox2, which exhibit similar and specific structure and regulation features. Their biological functions are still poorly understood and were initially mostly deduced from their specific tissue expression profiles. However, recent functional data have emerged that suggest the involvement of several of these isoforms in the innate host response to invading microorganisms, including innate immune and proinflammatory responses. Nox2 is well characterized as a key player in the bacterial killing process that takes place in phagocytes. Here, we will discuss the recent advances that revealed alternative roles of Nox1, Nox4, Duox1 and Duox2 isoforms in other aspects of the innate host defense. In particular, we will focus on their implication in the signaling following pathogen recognition by toll like receptors and in the modulation of dendritic cell functions, two key aspects of innate immunity. Moreover, the potential role of Nox/Duox enzymes in the innate response to virus infections will be discussed.