key: cord-0955317-fczbztng
authors: Guo, Shanshan; Bao, Lei; Li, Chun; Sun, Jing; Zhao, Ronghua; Cui, Xiaolan
title: Antiviral activity of iridoid glycosides extracted from Fructus Gardeniae against influenza A virus by PACT-dependent suppression of viral RNA replication
date: 2020-02-05
journal: Sci Rep
DOI: 10.1038/s41598-020-58443-3
sha: 197489ce2e74e5566e1cd13fdce4a26b4eba45f6
doc_id: 955317
cord_uid: fczbztng

Epidemic and pandemic influenza A virus (IAV) poses a significant threat to human populations worldwide. Iridoid glycosides are principal bioactive components from the Gardenia jasminoides J. Ellis fruit that exhibit antiviral activity against several strains of IAV. In the present study, we evaluated the protective effect of Fructus Gardeniae iridoid glycoside extracts (IGEs) against IAV by cytopathogenic effect(CPE), MTT and a plaque formation assay in vitro and examined the reduction in the pulmonary index (PI), restoration of body weight, reduction in mortality and increases in survival time in vivo. As a host factor, PACT provides protection against the pathogenic influenza A virus by interacting with IAV polymerase and activating the IFN-I response. To verify the whether IGEs suppress IAV replication in a PACT-dependent manner, IAV RNA replication, expression of PACT and the phosphorylation of eIF2α in A549 cells were detected; the levels of IFNβ, PACT and PKR in mouse lung tissues were determined; and the activity of IAV polymerase was evaluated in PACT-compromised cells. The results indicated that IGEs sufficiently alleviated cell damage and suppressed IAV replication in vitro, protecting mice from IAV-induced injury and lethal IAV infection. These anti-IAV effects might be related to disrupted interplay between IVA polymerase and PACT and/or prevention of a PACT-dependent overactivated IFN-I antiviral response. Taken together, our findings reveal a new facet of the mechanisms by which IGEs fight the influenza A virus in a PACT-dependent manner.

Influenza virus polymerase requires a large number of host cell factors to engage in the viral RNA transcription and replication processes 19, 20 . The interactions between influenza polymerase and host cell factors were identified by diverse methods, such as genome-wide RNA interference (RNAi) screens 21 , proteomic approaches 22 , and systematic immunoprecipitation analysis 23 . Host factor PACT is a double-stranded RNA-binding protein that is also known to be an activator of the cellular dsRNA-dependent protein kinase, PKR 24 . PACT is involved in the interaction between influenza A virus (IAV) and host cells, and it can substantially enhance RIG-I activation and phosphorylate eukaryotic translation initiation factor 2 alpha (eIF2α) to induce an IFN type I response, which is suppressed by the nonstructural influenza virus protein NS1 25, 26 . Recently, researchers have emphasized that, during IAV infection, PACT exerts its antiviral activity primarily by interacting with and inhibiting IAV polymerase. It has been demonstrated that PACT is associated with PA, PB1, and PB2 27 . Compromising PACT in IAV-infected A549 cells led to the enhancement of vRNA transcription and replication and IFNβ production. In addition, vRNA replication was increased by knocking down PACT in both A549 cells and IFN-insufficient Vero cells 28 .

Iridoid glycosides are the principal bioactive components in Fructus Gardeniae, which has antiviral and anti-inflammatory characteristics and has been used as a general Chinese herbal medicine for centuries in several Asian counties 29 . It has been reported that geniposide, a main iridoid glycoside compound extracted from Gardenia jasminoides J. Ellis fruit, effectively blocked cell damage induced by the pandemic A/Jiangsu/1/2009 (H1N1) influenza virus and alleviated virus-induced acute lung injuries 30 . In our previous study, it was demonstrated that Fructus Gardeniae iridoid glycoside extracts (IGEs) exhibited antiviral effects against influenza A virus H1N1 and H3N2 subtypes in vitro and in vivo 31 . RNA replication of the influenza virus A/FM1/47 was inhibited by IGEs in a dose-dependent manner, but the underlying mechanism has not yet been deciphered.

In the present study, we first determined the protective effect of the Fructus Gardeniae iridoid glycosides extracts (IGEs) on the cells and mice infected by influenza A virus. Next, we investigated whether the IGEs could inhibit vRNA replication and host factor PACT activation by evaluating the levels of virus replication, protein expression of PACT and phosphorylation of eIF2α in A549 cells and the levels of IFNβ, PACT and PKR in mouse lung tissues. In addition, to assess whether IGEs inhibit influenza virus replication in PACT-dependent manner, we measured RNA polymerase activity of influenza virus in HEK-293T cells in which PACT protein expression was knocked down by siRNA.

In the present study, the anti-influenza virus activity of the IGEs was measured by visualizing the CPE. MDCK cells showed a significant cytopathic effect (rounding and sloughing) at 48 h post infection, and the IGEs obviously inhibited the influenza virus A/FM1/47 (Fig. 1A) .

To evaluate the protective effect of the IGEs on the MDCK cells induced by influenza virus, cell viability was further examined by MTT assay. Moreover, the MDCK cell virus titre was analysed by plaque formation assay. In the virus control group, cell viability was dramatically decreased, to 43.85%. IGEs treatment significantly increased the cell viability, to 85.08%, 79.26%, 63.92% and 57.60%, at concentrations of 320, 160, 80 and 40 μg/ml, respectively (Fig. 1B) . Virus titres of the MDCK cells infected with influenza virus were markedly decreased by IGEs treatments (320, 160, 80 and 40 μg/ml) in a dose-dependent manner (Fig. 1C) . The findings indicated that the influenza virus A/FM/1/47 was sensitive to IGEs treatment in vitro.

In the current study, the anti-influenza activity of the IGEs in vivo was measured using PI and IRPI. PI was calculated to assess lung oedema. Mice in the virus control group presented with an increased PI (1.24 ± 0.04) compared to that presented by the normal control group (0.77 ± 0.02). Compared with that of the virus control group, groups treated with IGEs at doses of 20, 10, or 5 mg/kg presented with significantly decreased dose-dependent PI ( Fig. 2A) . In addition, groups treated with IGEs showed substantially inhibited PI activity, with the rate of the pulmonary index (IRPI) decrease of 54.40%, 46.23%, and 34.55% at the 20, 10, and 5 mg/kg dose, respectively (Fig. 2B ).

IGEs treatment protected mice from lethal influenza challenge. To evaluate the protective efficacy of IGEs against lethal influenza challenge, the change in body weight, reduction in mortality and prolonged survival time were estimated for the Balb/c mice. In the virus control group, the weight of the mice had mildly increased at 4 days post-infection, while at 8 days post-infection, the weight of mice had decreased to its minimum value. From 11 to 14 days post-infection, the weight of the mice visibly increased. IGEs treatment restored the body weight loss at 4, 8, 11, and 14 days post-infection (Fig. 3A) .

Fourteen days after infection, 19 of the 20 mice in virus control group died, and the mortality was 95%. The mortality was significantly decreased to 45%, 60% and 75% by IGEs treatment at doses of 20, 10 and 5 mg/kg for the mice in the other groups compared to those in the virus control group. Moreover, IGEs treatment protected 11/20, 8/20, and 5/20 mice (55%, 40%, and 25%) from death at doses of 20, 10, and 5 mg/kg, respectively (Fig. 3B ). In addition, IGEs treatment (20, 10 and 5 mg/kg) dramatically increased the survival time of the mice by 11.2, 10.7, 9. 95 days compared to the survival time for the mice in the virus control group (Fig. 3C ). www.nature.com/scientificreports www.nature.com/scientificreports/ Effect of IGEs on IFNβ production and PACT and PKR expression levels. PACT functions as an activator of RIG-I to facilitate the viral induction of type I IFNs. To verify the type I IFN response induced by IAV infection, the levels of IFNβ, PACT and PKR in the lung tissues were evaluated by ELISAs. Five days after the mice were inoculated with influenza virus A/FM1/47, the levels of IFNβ, PACT and PKR were remarkably more pronounced. Hence, IAV infection induced the type I IFN antiviral response that is activated by PACT and PKR. IGEs treatment significantly decreased IFNβ production at doses of 20, 10, and 5 mg/kg in a dose-dependent manner (Fig. 5A) . Furthermore, as shown in Fig. 5B and Fig. 5C , the elevated levels of PACT and PKR in lung tissues of IAV-infected mice were depressed by the IGEs administered at doses of 20, 10, and 5 mg/kg. Typical CPE characteristics, cell rounding and crimpling were observed in the virus control group, but were significantly alleviated in the ribavirin group and the IGEs treatment group. (B) MDCK cell viability of cells was evaluated by MTT assay. Each value was expressed as the mean ± SEM(n = 4). **P < 0.01 compared to the cell control group, ## P < 0.01 and # P < 0.05 compared to the virus control group. (C) The value of virus titres for each group represented. Virus titres are shown as -lgTCID 50 and expressed as the mean ± SEM (n = 6). **P < 0.01 compared to the cell control group, and ## P < 0.01 compared to the virus control group. (2020) 10:1897 | https://doi.org/10.1038/s41598-020-58443-3 www.nature.com/scientificreports www.nature.com/scientificreports/ was inhibited by IGEs treatment at all time points (Fig. 6F ). These results indicated that the overactivation of PACT induced by IAV was suppressed by IGEs treatment.

above, we demonstrated that IGEs suppressed virus replication and PACT overactivation. To clarify whether the IGEs inhibited virus replication in a PACT-dependent manner, IAV polymerase activity was determined in the HEK-293T cells in which PACT protein expression was knocked down by siRNA. When PACT was depleted, RNA polymerase activity was more robust. Hence, virus replication that was catalysed by IAV polymerase was enhanced by the knockdown of PACT. In PACT-deficient HEK-293T cells, suppression of IAV polymerase activity was remarkably more robust at IGEs treatment doses of 320 and 160 μg/ml when PACT was not knocked down. The results suggested that the IGEs might inhibit virus replication in a PACT-dependent manner (Fig. 7 ).

Influenza virus causes severe respiratory illness annually, especially in elderly and immunocompromised individuals, leading to complications and hospitalization, and in some case, even death 32 . The currently used first-line drugs for the prevention and the treatment of influenza are neuraminidase inhibitors (NAIs), represented by oseltamivir 33 . However, the rapid emergence and spread of resistance to oseltamivir have created an urgent need for developing novel anti-influenza drugs with different mechanisms of action 34 . Some studies have reported that iridoid glycosides extracted from Fructus Gardeniae possess antiviral activity against influenza, including strains A/FM/1/47-MA, pandemic A/Jiangsu/1/2009, in vitro and in vivo 35, 36 . Despite its great therapeutic potential, the IGEs ability to suppress virus replication or improve innate immune function was poorly understood.

In the present study, the results demonstrated that IGEs possess potent antiviral properties against influenza virus A/FM1/47. It could alleviate the cell damage and reduce plaque formation induced by the H1N1 subtype of influenza A virus at non-cytotoxic concentrations in a dose-dependent manner in vitro.

The pathogenic influenza A virus (H1N1) causes respiratory tract infection that develops into severe influenza pneumonia, leading to acute pulmonary injury (ALI) 37, 38 and acute respiratory distress syndrome (ARDS) 39, 40 , even to death. In this study, we successfully established a mouse model of IAV pneumonia and death in which mice were infected with influenza virus A/FM1/47. In the mouse model of IAV pneumonia, IGEs exhibited an inhibitory effect on the pulmonary index, which indicated that the IGEs protected the lung tissues from influenza-induced injury. Of note, in the mouse death model, changes in body weight, reduced mortality and prolonged survival time suggested that IGEs treatment sufficiently protected and rescued mice from lethal IAV infection.

To verify whether IGEs inhibited virus replication, the expression of the influenza M1 gene in A549 cells was determined by quantitative real-time PCR. The results showed that virus replication in the A549 cells increased significantly 4, 6, 8, 10, and 24 h post-infection. In particular, the relative value indicating virus replication was Type I interferon (IFN-I) is a key component of the innate antiviral response, and constitutes the first line of host defence against influenza virus infection [41] [42] [43] . The activation of the IFN-I response requires PACT, which interacts with RNA polymerase, and nonstructural proteins NS1 and NS2 of influenza A virus 44 . Influenza virus replication depends on the interaction of virus-encoded proteins with host factors, which regulate pivotal aspects of cell survival; virus recognition, replication and pathogenicity; and host defence 45, 46 . It has been reported that PACT is a crucial antiviral host factor that mediates the activation of the dsRNA-dependent kinase PKR, and stimulates substantial RIG-I activation to induce IFN-I production 47 . When PACT was co-expressed with RIG-I, the IFNβ promoter activity induced by IAV RNP complex was most robust 48 .

The outcome of IAV infection depends on the intricate interactions between the virus and the host. When IAV prevails, the antiviral activity of IFNs can insufficiently inhibit IAV replication, and the accumulation of vRNA and RNP results in overactivation of IFNs, which might lead to the development of pathological inflammation. In contrast, when IFNs prevail, IAV replication is suppressed and eventually cleared 49, 50 . In the current study, IFNβ, PKR and PACT levels were remarkably elevated in the lung tissues of mice infected with IAV. The results indicated that IAV infection induced an IFN-I response in the mice and that PACT enhanced the activation of the PKR and IFN response, findings consistent with those from a recently reported study 51, 52 . IGEs treatment at doses of 20, 10, 5 mg/kg significantly decreased the IFNβ production and depressed the elevated levels of PACT and PKR in lung tissues of the IAV-infected mice. Our findings revealed that IGEs might protect the IAV-infected mice from pneumonia and death by inhibiting the overactivation of the IFN response induced by PACT.

In response to stress signals induced by viral infection, four mammalian serine-threonine kinases phosphorylate the eukaryotic protein translation initiation factor 2α (eIF2α), including HRI, GCN2, PERK and PKR 53 . Among these kinases, IFN-I-induced PKR plays a crucial role in the anti-viral innate immune response against the influenza A virus. PACT-dependent PKR activation leads to phosphorylation of eIF2α, which results in the arrest of translation of both cellular and viral mRNAs, which is an efficient way to suppress virus replication 54, 55 .

To verify the activation of PACT and eIF2α induced by IAV infection, we measured PACT expression and eIF2α phosphorylation in infected A549 cells 12, 24, 36, and 48 h post-infection. In the current study, PACT www.nature.com/scientificreports www.nature.com/scientificreports/ www.nature.com/scientificreports www.nature.com/scientificreports/ general agreement with a previous report 56 . Furthermore, IGEs treatment markedly inhibited PACT expression in a dose-dependent manner at the three measurement time points post-infection. Interestingly, eIF2α phosphorylation was significantly suppressed by IGEs treatment at four time points. These results indicated that the overactivation of PACT and eIF2α phosphorylation induced by IAV was suppressed by IGEs treatment, which provides evidence that IGEs exert anti-IAV activity by inhibiting the overactivation of the PACT-dependent innate immune response.

PACT has been identified as an antiviral host factor that interacts with IAV polymerase. The interaction between PACT and IAV polymerase plays a pivotal role in the outcome of virus infection and antiviral immune response. It has been demonstrated that PACT-dependent activation of IFNβ production was inhibited by all three subunits of IAV polymerase 57, 58 . In an RNP reconstitution assay, knocking down PACT in IAV-infected A549 cells enhanced vRNA production and the subsequent IFN response 59 . Of interest, there might be interplay between PACT and other viral molecules, such as the herpes simplex virus type 1 (HSV-1) Us11 protein, Middle East respiratory syndrome coronavirus (MERS-CoV) 4a and the nucleocapsid of the Ebola virus (EBOV) VP35, mouse hepatitis virus (MHV) N proteins and influenza A virus NS1 [60] [61] [62] [63] . Hence, PACT might be a common target to counteract innate immunity response induced by different viruses with the potential to be developed into a new broad-spectrum antiviral drug.

To further investigate whether IGEs suppresses IAV replication in a PACT-dependent manner, PACT was compromised by siRNA in HEK-293T cells that had been co-transfected with four plasmids containing NP, PA, PB1 and PB2. According to the results of the dual-luciferase reporter gene assay, the HEK-293T cells transfected with only with pFlu-luc showed very low relative luciferase activity for the IAV RNA polymerase. In contrast, cells co-transfected with plasmids containing NP, PA, PB1, PB2 and Flu-luc showed relatively high RNA polymerase activity. Of note, our results indicated that knocking down PACT enhanced IAV polymerase activity, a finding that was consistent with that of a previous study. Hence, virus replication that was catalysed by IAV polymerase was enhanced by compromising the action of PACT, which was identified as an antiviral host factor. In addition, IGEs treatment at doses of 320 and 160 μg/ml showed a relatively weak suppressive effect on IAV polymerase activity in the PACT-knockdown HEK-293T cells. Collectively, the data from the current study demonstrated that IGEs treatment might inhibit IAV replication in a PACT-dependent manner.

In conclusion, our research indicated that IGEs sufficiently alleviated cell damage and suppressed IAV replication in vitro, protected the lung tissues from IAV-induced injury in mice models of influenza-induced pneumonia and rescued mice from lethal IAV infection. These anti-IAV effects might be related to disrupted interplay between the IVA polymerase and the cellular double-stranded RNA-binding protein PACT, which prevents the overactivation of the PACT-dependent IFN-I antiviral response induced by IAV infection. Taken together, our findings reveal a new facet of the mechanism of IGEs action against the influenza A virus, for which it inhibited IAV replication in a PACT-dependent manner. The current study might pave the way for the development of new antiviral agents against IAV. Sample preparation. First the powder of dried fruits (2 kg) was reflux-extracted twice with 70% ethanol, and then the extracts were combined and centrifuged. Next, the supernatant fluid was vacuum dried to remove traces of alcohol, and the concentrated solution was diluted with water to a mass concentration of 0.5 g/ml. The filtrate was passed through AB-8 macroporous resin and then successively eluted with water and 50% ethanol. www.nature.com/scientificreports www.nature.com/scientificreports/ The 50% ethanol eluted fractions were combined and dried as the extract sample. The sample was stored at 4°C and dissolved in double distilled water at the time of use. The purity of the geniposide was 39.4%, and the purity of the iridoid glycosides in the sample was > 90%, as detected by UV spectrophotometry(T6, Beijing General Instrument Co. LTD, Beijing, China).

Disease Control and Prevention, Chinese Center for Disease Control and Prevention. The virus stock was prepared by infecting 10-day-old specific-pathogen-free embryonated chicken eggs (Merial Vital Laboratory Animal Technology Co., Ltd, Beijing, China) for 48 h at 35°C. The virus titre (expressed as 50% tissue culture infective dose, TCID 50 ) was calculated to be 10 −4.5 in the MDCK cells by the Reed-Muench method 64 .

MDCK, A549 and HEK-293T cells were purchased from the Cell Center, Institute of Basic Medical Sciences, Peking Union Medical College (Beijing, China) and cultivated in DMEM supplemented with 10% foetal bovine serum and 1% penicillin/streptomycin (all from Gibco).

Animals. ICR mice (13-15 g) and Balb/c mice (18-22 g) were obtained from Vital River Laboratory Animal Technology Co., Ltd. in Beijing, China, and acclimated with standard feed and water in the following conditions (temperature: 20 ± 2°C, humidity: 50 ± 10%). All experiments were performed in compliance with the rules of the European Community Guidelines for the care and use of animals. The study was approved by the Ethics Committee at Institute of Chinese Materia Medica, China Academy of Chinese Medical Sciences.

In vitro antiviral assay. MDCK cells were cultured in 96-well plates at a density of 5×10 5 cells/ml, and exposed to the FM/1/47 strain of H1N1 influenza virus at 100 TCID 50 for 1 h. Then, the infected cells were incubated for 48 h with serially diluted IGEs solutions, to final concentrations were of 320, 160, 80 and 40μg/ml. Ribavirin was used as a positive drug control, at a final concentration of 3.13 mg/ml. After incubation at 37 °C for 48 h, the infected cells showed a significant cytopathic effect (CPE), distinguished by rounding and sloughing. The inhibition effect of IGEs on the CPE induced by influenza A virus was determined by MTT assay. Cell viability was expressed as the percentage of the cell control group (100%). The virus titres were quantified by plaque formation assay and presented as the negative lg 50% tissue culture infectious dose (-lgTCID 50 ) 65 .

Animal infection and treatment. Normal control group, virus-infection control Sixty ICR mice (13-15 g), 30 males and 30 females, were randomly separated into six groups: group, ribavirin treatment group (82.5 mg/ kg), and three IGEs treatment groups based on administered IGEs dose: 20, 10 and 5 mg/kg. All mice except those in the normal control group were infected intranasally with 40 μL of viral suspension of influenza virus/A/ FM/1/47(H1N1) at a concentration of 15 times of median lethal dose (LD 50 ). In the treatment groups, the inoculated mice were successively given daily doses of IGEs or ribavirin orally for 4 days beginning on the day of infection. Each mouse in the control group was given a volume of distilled water equal to that of the IGEs treatment volume. On day 5, all the mice were sacrificed, and the body weight (BW) and lung weight (LW) of each were determined to calculate the pulmonary index (PI) and the inhibitory rate of pulmonary index (IRPI). PI = [LW(g)/BW(g)]×100, IRPI = [(LW of virus control group-LW of treatment group)/(LW of virus control group-LW of normal control group)] ×100. The lung tissues were collected and subjected to an ELISA.

A total of 100 Balb/c mice were randomly distributed into five groups with 20 mice per group: the virus-infection control group, ribavirin treatment group, and three IGEs treatment groups. All the mice were infected with 45 μL of the influenza virus strain A/FM/1/47 solution at a concentration 8-fold greater than that of the LD 50 by intranasal instillation. In the treatment groups, the inoculated mice were successively given IGEs orally at a dose of 20 ml/kg, 10 ml/kg or 5 ml/kg, or treated with 82.5 mg/kg ribavirin daily for 5 days at the beginning of the infection day. Each mouse in the control group received a volume of distilled water equal to the treatment volume. Body weight changes were determined at days 0, 4 8, 11 , and 14 post-infection, and the survivals of the mice were recorded every day for 14 consecutive days. The protective effect against the lethal challenge was determined as increased body weight, reduction in mortality and prolonged survival time.

Influenza virus replication levels detected by qRT-PCR. The levels of influenza virus A/FM/1/47 replication in MDCK cells were detected by quantitative real-time RT-PCR. Total cellular RNA was extracted 4, 6, 8, 10, and 24 h post-infection by TRIzol reagent (Invitrogen, USA) according to the manufacturer's instructions. The QRT-PCR assay was performed using the one-step SYBR PrimeScript RT-PCR kit (TaKaRa, Japan) according to the manufacturer's protocol (for the influenza virus A/FM/1/47 M protein genes the forward primer was 5′-ATCATTGGGATCTTGCACTT-3′, and the reverse primer was 5′-TCATAGACTCTGGCACTCCTT-3′, and for GAPDH, the forward primer was 5′-CCCACTCCTCCACCTTTGACG-3′, and the reverse primer was 5′-CACCACCCTGTTGCTGTAGCCA-3′). The transcript levels of influenza virus A/FM/1/47 and GAPDH were calculated by the ΔΔCT method. PCR was carried out using a quantitative PCR instrument (Thermo, USA) under the following conditions: 42 °C for 5 min, 95 °C for 10 sec followed by 40 cycles of 95 °C for 5 sec and 60 °C for 34 sec. The inhibitory rate of virus replication = 1 − (relative value of virus replication in the treatment group)/(relative value of virus replication in the virus control group).

ELISAs for determining IFNβ, PACT and PKR levels. The levels of IFNβ, PACT and PKR in the mouse lung tissues were detected by enzyme-linked immunosorbent assay (Elisa) kits (96 T, Meilian Co., Ltd, Shanghai, China) following the manufacturer's instructions.

The use of nonhuman primates in research on seasonal, pandemic and avian influenza

Within-Host Models of High and Low Pathogenic Influenza Virus Infections: The Role of Macrophages

Antigenically diverse swine-origin H1N1 variant influenza viruses exhibit differential ferret pathogenesis and transmission phenotypes

Emergence and spread of highly pathogenic avian influenza A(H5N8) in Europe in 2016-2017

Genetic Characteristic and Global Transmission of Influenza A H9N2 Virus

Convergent Evolution of Human-Isolated H7N9 Avian Influenza A Viruses

The temporal distribution of new H7N9 avian influenza infections based on laboratory-confirmed cases in Mainland China

Epidemiology of avian influenza A H7N9 virus in human beings across five epidemics in mainland China, 2013-17: an epidemiological study of laboratory-confirmed case series

Antiviral combinations for severe influenza

Molecular analysis of amantadine-resistant influenza A (H1N1 pdm09) virus isolated from slum dwellers of Dhaka

Five years of monitoring for the emergence of oseltamivir resistance in patients with influenza A infections in the Influenza Resistance Information Study

Influenza A virus polymerase: an attractive target for next-generation anti-influenza therapeutics

NMR spectra of PB2 627, the RNA-binding domain in influenza A virus RNA polymerase that contains the pathogenicity factor lysine 627, and improvement of the spectra by small osmolytes

Structural insight into cap-snatching and RNA synthesis by influenza polymerase

Capped RNA primer binding to influenza polymerase and implications for the mechanism of cap-binding inhibitors

Influenza virus polymerase: Functions on host range, inhibition of cellular response to infection and pathogenicity

Generation and comprehensive analysis of an influenza virus polymerase cellular interaction network

Human host factors required for influenza virus replication

Comprehensive proteomic analysis of influenza virus polymerase complex reveals a novel association with mitochondrial proteins and RNA polymerase accessory factors

Influenza virus-host interactome screen as a platform for antiviral drug development

Inhibition of the inflammatory response to stress by targeting interaction between PKR and its cellular activator PACT

Quantitative proteomic analysis of the influenza A virus nonstructural proteins NS1 and NS2 during natural cell infection identifies PACT as an NS1 target protein and antiviral host factor

Viral inhibitions of PACT-induced RIG-I activation

Interactions between the influenza A virus RNA polymerase components and retinoic acid-inducible gene I

Antiviral activity of double-stranded RNA-binding protein PACT against influenza A virus mediated via suppression of viral RNA polymerase

Iridoid and bis-iridoid glucosides from the fruit of Gardenia jasminoides

Geniposide demonstrates anti-inflammatory and antiviral activity against pandemic A/Jiangsu/1/2009 (H1N1) influenza virus infection in vitro and in vivo

The inhibitory effect of iridoid glycoside extracted from Fructus Gardeniae on intracellular acidification and extracellular Ca2+ influx induced by influenza A virus

Potent and broad-spectrum cycloheptathiophene-3-carboxamide compounds that target the PA-PB1 interaction of influenza virus RNA polymerase and possess a high barrier to drug resistance

New small-molecule drug design strategies for fighting resistant influenza A

Determining the Mutation Bias of Favipiravir in Influenza Virus Using Next-Generation Sequencing

Bioactivity-guided fractionation and analysis of compounds with anti-influenza virus activity from Gardenia jasminoides Ellis

Comparative analysis of sixteen active compounds and antioxidant and anti-influenza properties of Gardenia jasminoides fruits at different times and application to the determination of the appropriate harvest period with hierarchical cluster analysis

Combination of sphingosine-1-phosphate receptor 1 (S1PR1) agonist and antiviral drug: a potential therapy against pathogenic influenza virus

Neutrophils Induce a Novel Chemokine Receptors Repertoire During Influenza Pneumonia

Excess mortality is associated with influenza A (H1N1) in patients with severe acute respiratory illness

Outcomes of severe H1N1 pneumoniae: A retrospective study at intensive care units

Cell-Penetrating Mx1 Enhances Anti-Viral Resistance against Mucosal Influenza Viral Infection

Type I Interferons: Distinct Biological Activities and Current Applications for Viral Infection

Obesity worsens the outcome of influenza virus infection associated with impaired type I interferon induction in mice

Contribution of the two dsRBM motifs to the doublestranded RNA binding and protein interactions of PACT

Evaluation of the Antiviral Activity of Sephin1 Treatment and Its Consequences on eIF2alpha Phosphorylation in Response to Viral Infections

Double Plant Homeodomain Fingers 2 (DPF2) Promotes the Immune Escape of Influenza Virus by Suppressing Beta Interferon Production

Viral proteins targeting host protein kinase R to evade an innate immune response: a mini review

Standing on three legs: antiviral activities of RIG-I against influenza viruses

Highly pathogenic H5N1 influenza A virus strains provoke heterogeneous IFN-alpha/beta responses that distinctively affect viral propagation in human cells

Innate immune sensing and response to influenza

The dual role of innate immunity during influenza

Host Cell Restriction Factors that Limit Influenza A Infection

Influenza Virus Infections and Cellular Kinases

Influenza a virus host shutoff disables antiviral stress-induced translation arrest

PKR Transduces MDA5-Dependent Signals for Type I IFN Induction

Comprehensive profiling of translation initiation in influenza virus infected cells

Influenza virus adaptation PB2-627K modulates nucleocapsid inhibition by the pathogen sensor RIG-I

The interaction of cellular protein ANP32A with influenza A virus polymerase component PB2 promotes vRNA synthesis

PACT-and RIG-I-Dependent Activation of Type I Interferon Production by a Defective Interfering RNA Derived from Measles Virus Vaccine

Suppression of PACT-induced type I interferon production by herpes simplex virus 1 Us11 protein

Middle east respiratory syndrome coronavirus 4a protein is a double-stranded RNA-binding protein that suppresses PACT-induced activation of RIG-I and MDA5 in the innate antiviral response

Mutual antagonism between the Ebola virus VP35 protein and the RIG-I activator PACT determines infection outcome

The nucleocapsid proteins of mouse hepatitis virus and severe acute respiratory syndrome coronavirus share the same IFN-beta antagonizing mechanism: attenuation of PACT-mediated RIG-I/ MDA5 activation

Isolation and quantitation of HIV in peripheral blood

Plaque formation assay for human parainfluenza virus type 1

Establishment of drug screening assay and pharmacodynamic evaluation method targeting influenza RNA polymerase

The project was funded by the following grants: National Natural Science Foundation of China (No. 81773977, 81303290), China Basic Research Projects of China Academy of Chinese Medical Sciences (No. ZZ0908034).

S.G. and X.C. designed the study; S.G., L.B., J.S. and R.Z. performed the antiviral experiment; C.L. prepared the IGEs samples of IGEs; S.G., L.B. analysed and interpreted the data; S.G. wrote the manuscript.

Shanshan Guo, Lei Bao, Chun Li, Jing Sun, Ronghua Zhao and Xiaolan Cui do not have any conflicts of interest with respect to this work.

Correspondence and requests for materials should be addressed to X.C.Reprints and permissions information is available at www.nature.com/reprints.Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.