Antiviral activity of type I interferons and interleukins 29 and 28a (type III interferons) against Apeu virus

Interferons (IFNs) are cytokines with important immunomodulatory activity in vertebrates. Although type I IFNs and interleukins (IL) 29 and 28a (type III IFNs) bind to different cellular receptors and have distinct structures, most of their biological activities are redundant. Apeu virus (APEUV) is a member of the Bunyaviridae family isolated from the Brazilian rain forest. In this paper we evaluated the antiviral activity of type I and type III IFNs against APEUV. All tested IFNs were able to induce an antiviral state against the virus in a dose-dependent way. The activity of type III IFNs did not need the presence of type I IFNs. Mixing both types of IFNs did not improve the biological activity of each type alone. The tested IFNs were also able to protect human peripheral blood mononuclear cells from infection. IFN alpha2, IFN beta, IL-29 and IL-28a induced the expression of 2′,5′-oligoadenylate synthetase (2′5′OAS) and 6–16 genes. Although MxA gene was related to antiviral activity against Bunyaviruses, there was no induction of MxA in our model. We were able to show activity of type I and type III IFNs against a RNA virus, and that this activity is not dependent on MxA gene.     

Antiviral activity of type I and type III interferons against porcine reproductive and respiratory syndrome virus (PRRSV)

The newly identified type III interferons (IFNs), also known as IFN-λ1/IL-29, IFN-λ2/IL-28A and IFN-λ3/IL-28B, like type I IFNs, have antiviral activity against a broad spectrum of viruses. We therefore examined whether type III IFNs, as well as type I IFNs, has the ability to inhibit porcine reproductive and respiratory syndrome virus (PRRSV) replication in MARC-145 cells. We found that replication of PRRSV in MARC-145 cells was significantly reduced following treatment with IFN-λ1, IFN-λ2 and IFN-λ3, respectively, and such inhibition was dose-dependent. However, type III IFNs (IFN-λ1, IFN-λ2 and IFN-λ3) was less effective than type I IFNs (IFN-α and IFN-β) in antiviral activity against PRRSV. Mixture of two types of IFNs could not improve the antiviral activity of each type alone. In addition, all types of IFNs in our study were able to induce the expression of ISG56, 2′,5′-OAS and MxA in MARC-145 cells. These data demonstrate that type III IFNs had antiviral activity against PRRSV and may serve as useful antiviral agents against infectious swine diseases.     

TT virus infection: role of interferons, interleukin-28 and 29, cytokines and antiviral proteins

In 1997 a novel virus in the serum of a patient with acute post-transfusion hepatitis of non A-G etiology was identified. This agent was designed TT virus (TTV). It produces persistent viremia and no disease, but the mechanism of its persistence is poorly understood. In the present study mRNA expression of antiviral proteins as MxA, 2' 5' OAS, anti-apopotic protein, cytokines IL- 28, IL- 29 and IFN are examined in a subject affected by B lymphoma and positive for TTV DNA and RNA in this cellular subset, and in BJAB and Dohh2 cell lines.     

Novel plant-derived recombinant human interferons with broad spectrum antiviral activity

Type I interferons (IFNs) are potent mediators of the innate immune response to viral infection. IFNs released from infected cells bind to a receptor (IFNAR) on neighboring cells, triggering signaling cascades that limit further infection. Subtle variations in amino acids can alter IFNAR binding and signaling outcomes. We used a new gene crossbreeding method to generate hybrid, type I human IFNs with enhanced antiviral activity against four dissimilar, highly pathogenic viruses. Approximately 1400 novel IFN genes were expressed in plants, and the resultant IFN proteins were screened for antiviral activity. Comparing the gene sequences of a final set of 12 potent IFNs to those of parent genes revealed strong selection pressures at numerous amino acids. Using three-dimensional models based on a recently solved experimental structure of IFN bound to IFNAR, we show that many but not all of the amino acids that were highly selected for are predicted to improve receptor binding.     

Novel plant-derived recombinant human interferons with broad spectrum antiviral activity

Type I interferons (IFNs) are potent mediators of the innate immune response to viral infection. IFNs released from infected cells bind to a receptor (IFNAR) on neighboring cells, triggering signaling cascades that limit further infection. Subtle variations in amino acids can alter IFNAR binding and signaling outcomes. We used a new gene crossbreeding method to generate hybrid, type I human IFNs with enhanced antiviral activity against four dissimilar, highly pathogenic viruses. Approximately 1400 novel IFN genes were expressed in plants, and the resultant IFN proteins were screened for antiviral activity. Comparing the gene sequences of a final set of 12 potent IFNs to those of parent genes revealed strong selection pressures at numerous amino acids. Using three-dimensional models based on a recently solved experimental structure of IFN bound to IFNAR, we show that many but not all of the amino acids that were highly selected for are predicted to improve receptor binding.     

白介素29体外抗乙肝病毒作用

目的研究白介素29(IL-29)体外抗乙肝病毒的效果。方法从RNA水平探讨了IL-29抗乙肝病毒的效果。RT-PCR分析IL-29诱导抗病毒蛋白MxA、2′,5-′OAS、PKR和RNase L mRNA水平表达;同时Western blot分析IL-29激活的信号通路以探讨其抗乙肝病毒的机理。结果IL-29能明显降低HepG2.2.15细胞中乙肝病毒mRNA的水平,且能够上调抗病毒蛋白MxA和2′,5-′OAS的mRNA表达并激活ERK1/2、AKT信号途径。结论在HepG2.2.15细胞中IL-29有显著的抗乙肝病毒作用。     

CpG and poly(I:C) stimulation of dendritic cells and fibroblasts limits herpes simplex virus type 1 infection in an IFNβ-dependent and -independent way

Viral activation of toll-like receptors (TLRs) on dendritic cells (DCs) leads to production of various cytokines, including antiviral type I interferons (IFNs). Synthetic ligands specific for TLRs are also able to induce the production of type I IFNs (IFNα/β) by DCs, suggesting that these ligands have potential as antiviral drugs. In this in vitro study we extensively investigated the antiviral activity of various TLR ligands. Mouse bone marrow (BM) cells were differentiated into plasmacytoid and conventional DCs (pDCs and cDCs), stimulated with various TLR ligands and tested the antiviral abilities of collected supernatants in an in vitro herpes simplex virus type 1 (HSV-1) infection model. We observed a significant IFNβ-, (but not IFNα-) dependent reduction in HSV-1 infection when a mixed pDC/cDC population was stimulated with the TLR9 ligand CpG. In the absence of pDCs, TLR stimulation resulted in less pronounced antiviral effects. The most pronounced antiviral effect was observed when both DC subsets were stimulated with poly(I:C). A similar noticeable antiviral effect was observed when fibroblasts (L929 cells) were stimulated directly with poly(I:C). These poly(I:C)-mediated antiviral effects were only partially IFNβ-mediated and probably TLR independent. These data demonstrate that TLR ligands are not only able to produce type I IFN but can indeed act as antiviral drugs. In particular poly(I:C), which exerts its antiviral effects even in the absence of DCs, may become a promising drug e.g. to prevent respiratory infections by topical intranasal application.     

Physicochemical and biologic properties of interferons and their potential uses in drug delivery systems.

Interferons (IFNs) are a complex group of proteins and glycoproteins able to express antiviral, immunomodulatory, and differentiation activities. In physiological conditions, they are produced upon induction, in basal amounts, and in restricted microenvironments where they act in a paracrine fashion, hardly reaching the circulation and not affecting parenchymal cells. In some acute infections, production of IFN is diffused and, therefore, IFN levels become detectable in plasma, and side effects, such as the typical flu-like syndrome, ensue. A similar situation occurs during pharmacological therapy, particularly when IFN is administered through conventional routes (IV, IM, and SC). We have finally realized that IFNs are normally not circulatory proteins, and because they are unselective during therapeutic intervention, toxicity can overcome beneficial effects. For this reason, there is a pressing need to optimize treatment, dosages, and schedules for improving the therapeutic index. A further important issue is the definition of routes of IFN administration able to achieve the maximal activity where needed, and in fact, when IFNs are used as cytostatic drugs, regional therapy improves the treatment. However, when IFNs are used as immunomodulatory agents, other strategies must be sought, and the interaction of IFN with epithelial membranes and mucosal associated lymphoid tissue becomes important. Hence, delivery via oropharyngeal, intestinal, rectal, bronchioalveolar, and lymphatic routes appears useful probably because they simulate the physiological distribution and action of IFNs.     

Influenza A virus replication is inhibited in IFN-λ2 and IFN-λ3 transfected or stimulated cells

Interferons lambda (IFN-λ) are the most recently defined members of the class III cytokine family. To investigate whether IFN-λ2 and IFN-λ3 displayed antiviral activity against influenza A virus (IAV), a number of cell lines induced with IFNs – as well as two established cell lines (A549-IFN-λ2 and A549-IFN-λ3) – were infected with IAV. Our results indicate that IFN-λ2 has statistically significant antiviral activity in A549-IFN-λ2 (P = 0.0028) although less so than IFN-λ3, which reduced viral titer to 10% (P < 0.0001). The reverse was observed for cells treated with IFNs, with IFN-λ2-treated A549 cells inhibiting IAV infection more efficiently than IFN-λ3-treated A549 cells. The antiviral effect on IFN-stimulated cells was most apparent on Vero cells (compared with MDCK and HeLa). Both IFNs significantly inhibited IAV replication and inhibition was observed in a dose-dependent manner, with an optimal IFN concentration of 20 ng/ml. IFN-λ2 was more potent than IFN-λ3 on Vero cells while IFN-λ3 appeared more efficient than IFN-λ2 on MDCK and HeLa cells.     

Influenza A virus replication is inhibited in IFN-λ2 and IFN-λ3 transfected or stimulated cells

Interferons lambda (IFN-λ) are the most recently defined members of the class III cytokine family. To investigate whether IFN-λ2 and IFN-λ3 displayed antiviral activity against influenza A virus (IAV), a number of cell lines induced with IFNs - as well as two established cell lines (A549-IFN-λ2 and A549-IFN-λ3) - were infected with IAV. Our results indicate that IFN-λ2 has statistically significant antiviral activity in A549-IFN-λ2 (P=0.0028) although less so than IFN-λ3, which reduced viral titer to 10% (P<0.0001). The reverse was observed for cells treated with IFNs, with IFN-λ2-treated A549 cells inhibiting IAV infection more efficiently than IFN-λ3-treated A549 cells. The antiviral effect on IFN-stimulated cells was most apparent on Vero cells (compared with MDCK and HeLa). Both IFNs significantly inhibited IAV replication and inhibition was observed in a dose-dependent manner, with an optimal IFN concentration of 20 ng/ml. IFN-λ2 was more potent than IFN-λ3 on Vero cells while IFN-λ3 appeared more efficient than IFN-λ2 on MDCK and HeLa cells.     

Inhibition of herpes simplex virus type 1 and adenovirus type 5 by heterocyclic Schiff bases of aminohydroxyguanidine tosylate

Eleven heterocyclic Schiff bases of aminohydroxyguanidine tosylate (SB-AHGs), compounds I-XI, were tested for antiviral activity against herpes simplex virus type 1 (HSV-1) and adenovirus type 5 (Ad 5) via plaque reduction and virus yield reduction assays. This work was undertaken to test the hypothesis that low molecular weight SB-AHGs (MW < 235 for the free SB) make better antiviral agents than high MW SB-AHGs (MW > 300). The plaque reduction assay method demonstrated that three compounds, I, VII and IX, had moderate activity against HSV-1, with 50% inhibitory concentration (IC50) values of 38.0, 23.5 and 52.1 microM, respectively. Against Ad 5, compounds I, VIII and XI exhibited moderate activity, with IC50 values of 52.7, 19.3 and 5.1 microM, respectively. Among the compounds screened, compound I (1-[(3'-hydroxy-6'-methyl-2'-pyridyl)methylene]amino-3-hydroxyguanidi ne tosylate) was the most promising antiviral candidate, with selectivity indices (SI) of 10.2 (HSV-1) and 7.6 (Ad 5), respectively. Virus yield reduction assays indicated that compound I had less antiviral potency against HSV-1 than against Ad 5. The antiviral effects of compound I at a high input virus multiplicity of infection (MOI > 5) indicated that compound I had effective anti-adenoviral activity at 24 h post infection. This work demonstrated that some of SB-AHGs only have moderate antiviral activities against Ad 5 and HSV-1 viruses. In general, low MW SB-AHGs have low cytotoxicities to the host cells.     

Interferons and their role In inflammation.

Cytokines are pleiotropic molecules showing a wide variety of biologic functions on various cells and tissues, and several different cytokines exert similar and overlapping functions on certain cells. Interferons (IFNs), among the first cytokines identified, play a crucial role in human disease. The IFN cytokine family consists of type I IFNs (IFN-a and IFN-b) and type II IFN (IFN-g). In the first decades of IFN research, type I IFNs were considered primarily as viral inhibitors, whereas type II IFN, also termed "immune IFN", was generally considered to be uniquely involved in immune reactions. This view has changed considerably in the last years. The importance of type I IFNs in inflammation, immunoregulation and T-cell responses has been identified and has changed dramatically our interpretation of the biological relevance of type I and II IFNs. Recent data suggest that IFN-a is a multifunctional immunomodulatory cytokine with profound effects on the cytokine cascade including several anti-inflammatory properties, whereas IFN-g remains a classical proinflammatory cytokine. These different effects on critical mediators of inflammation may also explain why type I and II IFNs are clinically successful in different diseases. These newly identified immunoregulatory and anti-inflammatory functions of type I IFNs may be of importance in the treatment of diseases such as chronic viral hepatitis or multiple sclerosis and help to explain some of the mechanisms of IFNs.     

Toll-like receptor 7-mediated enhancement of contextual fear memory in mice

Toll-like receptor (TLR) 7 recognizes viral single-stranded RNA and triggers production of the type I interferons (IFNs) IFN-α and IFN-β. Imiquimod, a synthetic TLR7 ligand, induces production of type I IFNs and is used clinically as an antiviral and antitumor drug. In the present study, we examined the effect of imiquimod on conditioned and innate fear behaviors in mice. Imiquimod was administered 2, 4, or 15 h before contextual fear conditioning. Imiquimod treatment 4 or 15 h before fear conditioning significantly enhanced context-dependent freezing behavior. This imiquimod-induced enhancement of fear-related behaviors was observed 120 h after fear conditioning. In contrast, imiquimod failed to enhance context-dependent freezing behavior in TLR7 knockout mice. Imiquimod had no significant effect on pain threshold or on innate fear-related behavior, as measured by the elevated plus-maze. The levels of type I IFN mRNA in the brain were significantly increased at 2 h after imiquimod treatment. Imiquimod also increased interleukin (IL)-1β mRNA expression in the brain at 4 h following administration, while mRNA expression of F4/80, a macrophage marker, was unaffected by imiquimod treatment. Our findings suggest that TLR7-mediated signaling enhances contextual fear memory in mice, possibly by inducing the expression of type I IFNs and IL-1β in the brain.     

TANK-binding kinase 1 as a novel therapeutic target for viral diseases

Introduction: TANK-binding kinase 1 (TBK1) is vital for the induction of antiviral innate immune responses. Both RNA and DNA viral infection induces TBK1 activation, triggers phosphorylation of interferon regulatory factor (IRF) 3 and subsequent expression of type I interferons (IFNs; IFN-α/β). Type I IFNs can induce the expression of numerous antiviral genes called interferon-stimulated genes (ISGs) to build a remarkable antiviral state and limit viral replication. Thus, optimal TBK1 activity is crucial for IRF3-induced type I IFNs expression and ISGs-mediated viral elimination.

Areas covered: This review provides an overview of the diverse roles of TBK1 in antiviral innate immune responses, the regulatory mechanisms of TBK1 activity and the implication in antiviral development.

Expert opinion: TBK1 is a key kinase against antiviral infection via inducing type I IFNs expression. Multiple types of post-translational modifications of TBK1 tightly regulate TBK1 activity and subsequent TBK1-dependent antiviral responses. The identified regulators of TBK1 unveil regulatory mechanisms of host antiviral innate immunity and immuno-escape mechanism of virus provide strategies to control viral diseases by modulating TBK1 activity.     

Type I Interferons as Regulators of Human Antigen Presenting Cell Functions

Type I interferons (IFNs) are pleiotropic cytokines, initially described for their antiviral activity. These cytokines exhibit a long record of clinical use in patients with some types of cancer, viral infections and chronic inflammatory diseases. It is now well established that IFN action mostly relies on their ability to modulate host innate and adaptive immune responses. Work in recent years has begun to elucidate the mechanisms by which type I IFNs modify the immune response, and this is now recognized to be due to effects on multiple cell types, including monocytes, dendritic cells (DCs), NK cells, T and B lymphocytes. An ensemble of results from both animal models and in vitro studies emphasized the key role of type I IFNs in the development and function of DCs, suggesting the existence of a natural alliance between these cytokines and DCs in linking innate to adaptive immunity. The identification of IFN signatures in DCs and their dysregulation under pathological conditions will therefore be pivotal to decipher the complexity of this DC-IFN interaction and to better exploit the therapeutic potential of these cells.