Host factors involved in influenza virus infection

2020 ◽  
Vol 4 (4) ◽  
pp. 401-410
Author(s):  
Matloob Husain
Keyword(s):  
Influenza Virus ◽  
Plasma Membrane ◽  
Life Cycle ◽  
Virus Infection ◽  
Mammalian Cells ◽  
Influenza Virus Infection ◽  
Host Factors ◽  
Tremendous Amount ◽  
Human Viruses ◽  
Insight Into

Influenza virus causes an acute febrile respiratory disease in humans that is commonly known as ‘flu’. Influenza virus has been around for centuries and is one of the most successful, and consequently most studied human viruses. This has generated tremendous amount of data and information, thus it is pertinent to summarise these for, particularly interdisciplinary readers. Viruses are acellular organisms and exist at the interface of living and non-living. Due to this unique characteristic, viruses require another organism, i.e. host to survive. Viruses multiply inside the host cell and are obligate intracellular pathogens, because their relationship with the host is almost always harmful to host. In mammalian cells, the life cycle of a virus, including influenza is divided into five main steps: attachment, entry, synthesis, assembly and release. To complete these steps, some viruses, e.g. influenza utilise all three parts — plasma membrane, cytoplasm and nucleus, of the cell; whereas others, e.g. SARS-CoV-2 utilise only plasma membrane and cytoplasm. Hence, viruses interact with numerous host factors to complete their life cycle, and these interactions are either exploitative or antagonistic in nature. The host factors involved in the life cycle of a virus could be divided in two broad categories — proviral and antiviral. This perspective has endeavoured to assimilate the information about the host factors which promote and suppress influenza virus infection. Furthermore, an insight into host factors that play a dual role during infection or contribute to influenza virus-host adaptation and disease severity has also been provided.

scholarly journals DDX3 Interacts with Influenza A Virus NS1 and NP Proteins and Exerts Antiviral Function through Regulation of Stress Granule Formation

2016 ◽  
Vol 90 (7) ◽  
pp. 3661-3675 ◽  
Author(s):  
Sathya N. Thulasi Raman ◽  
Guanqun Liu ◽  
Hyun Mi Pyo ◽  
Ya Cheng Cui ◽  
Fang Xu ◽  
...  
Keyword(s):  
Influenza Virus ◽  
Life Cycle ◽  
Virus Infection ◽  
Influenza A ◽  
Influenza Virus Infection ◽  
Ns1 Protein ◽  
Antiviral Protein ◽  
Virus Life Cycle ◽  
Interaction Partners ◽  
Infected Cells

ABSTRACTDDX3 belongs to the DEAD box RNA helicase family and is a multifunctional protein affecting the life cycle of a variety of viruses. However, its role in influenza virus infection is unknown. In this study, we explored the potential role of DDX3 in influenza virus life cycle and discovered that DDX3 is an antiviral protein. Since many host proteins affect virus life cycle by interacting with certain components of the viral machinery, we first verified whether DDX3 has any viral interaction partners. Immunoprecipitation studies revealed NS1 and NP as direct interaction partners of DDX3. Stress granules (SGs) are known to be antiviral and do form in influenza virus-infected cells expressing defective NS1 protein. Additionally, a recent study showed that DDX3 is an important SG-nucleating factor. We thus explored whether DDX3 plays a role in influenza virus infection through regulation of SGs. Our results showed that SGs were formed in infected cells upon infection with a mutant influenza virus lacking functional NS1 (del NS1) protein, and DDX3 colocalized with NP in SGs. We further determined that the DDX3 helicase domain did not interact with NS1 and NP; however, it was essential for DDX3 localization in virus-induced SGs. Knockdown of DDX3 resulted in impaired SG formation and led to increased virus titers. Taken together, our results identified DDX3 as an antiviral protein with a role in virus-induced SG formation.IMPORTANCEDDX3 is a multifunctional RNA helicase and has been reported to be involved in regulating various virus life cycles. However, its function during influenza A virus infection remains unknown. In this study, we demonstrated that DDX3 is capable of interacting with influenza virus NS1 and NP proteins; DDX3 and NP colocalize in the del NS1 virus-induced SGs. Furthermore, knockdown of DDX3 impaired SG formation and led to a decreased virus titer. Thus, we provided evidence that DDX3 is an antiviral protein during influenza virus infection and its antiviral activity is through regulation of SG formation. Our findings provide knowledge about the function of DDX3 in the influenza virus life cycle and information for future work on manipulating the SG pathway and its components to fight influenza virus infection.

scholarly journals Illumina-based sequencing framework for accurate detection and mapping of influenza virus defective interfering particle-associated RNAs

2018 ◽  
Author(s):  
Fadi G. Alnaji ◽  
Jessica R. Holmes ◽  
Gloria Rendon ◽  
J. Cristobal Vera ◽  
Chris Fields ◽  
...  
Keyword(s):  
Influenza Virus ◽  
Virus Infection ◽  
Influenza Virus Infection ◽  
Bioinformatics Pipeline ◽  
Base Calling ◽  
Large Numbers ◽  
Associated Sequences ◽  
Next Generation Sequencing Ngs ◽  
Insight Into ◽  
Defective Interfering Particle

AbstractThe mechanisms and consequences of defective interfering particle (DIP) formation during influenza virus infection remain poorly understood. The development of next generation sequencing (NGS) technologies has made it possible to identify large numbers of DIP-associated sequences, providing a powerful tool to better understand their biological relevance. However, NGS approaches pose numerous technical challenges including the precise identification and mapping of deletion junctions in the presence of frequent mutation and base-calling errors, and the potential for numerous experimental and computational artifacts. Here we detail an Illumina-based sequencing framework and bioinformatics pipeline capable of generating highly accurate and reproducible profiles of DIP-associated junction sequences. We use a combination of simulated and experimental control datasets to optimize pipeline performance and demonstrate the absence of significant artifacts. Finally, we use this optimized pipeline to generate a high-resolution profile of DIP-associated junctions produced during influenza virus infection and demonstrate how this data can provide insight into mechanisms of DIP formation. This work highlights the specific challenges associated with NGS-based detection of DIP-associated sequences, and details the computational and experimental controls required for such studies.

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

2017 ◽  
Vol 91 (12) ◽  
Author(s):  
Dongjo Shin ◽  
Jihye Lee ◽  
Ji Hoon Park ◽  
Ji-Young Min
Keyword(s):  
Influenza Virus ◽  
Virus Infection ◽  
Crucial Role ◽  
Influenza Virus Infection ◽  
Host Factors ◽  
Viral Escape ◽  
Type I ◽  
Plant Homeodomain ◽  
Novel Host ◽  
The Relationship

ABSTRACT The high mutation rates of the influenza virus genome facilitate the generation of viral escape mutants, rendering vaccines and drugs against influenza virus-encoded targets potentially ineffective. Therefore, we identified host cell determinants dispensable for the host but crucial for virus replication, with the goal of preventing viral escape and finding effective antivirals. To identify these host factors, we screened 2,732 human genes using RNA interference and focused on one of the identified host factors, the double plant homeodomain fingers 2 (DPF2/REQ) gene, for this study. We found that knockdown of DPF2 in cells infected with influenza virus resulted in decreased expression of viral proteins and RNA. Furthermore, production of progeny virus was reduced by two logs in the multiple-cycle growth kinetics assay. We also found that DPF2 was involved in the replication of seasonal influenza A and B viruses. Because DPF2 plays a crucial role in the noncanonical NF-κB pathway, which negatively regulates type I interferon (IFN) induction, we examined the relationship between DPF2 and IFN responses during viral infection. The results showed that knockdown of DPF2 resulted in increased expression of IFN-β and induced phosphorylation of STAT1 in infected cells. In addition, high levels of several cytokines/chemokines (interleukin-8 [IL-8], IP-10, and IL-6) and antiviral proteins (MxA and ISG56) were produced by DPF2 knockdown cells. In conclusion, we identified a novel host factor, DPF2, that is required for influenza virus to evade the host immune response and that may serve as a potential antiviral target. IMPORTANCE Influenza virus is responsible for seasonal epidemics and occasional pandemics and is an ongoing threat to public health worldwide. Influenza virus relies heavily on cellular factors to complete its life cycle. Here we identified a novel host factor, DPF2, which is involved in influenza virus infection. Our results showed that DPF2 plays a crucial role in the replication and propagation of influenza virus. DPF2 functions in the noncanonical NF-κB pathway, which negatively regulates type I IFN induction. Thus, we investigated the relationship between the IFN response and DPF2 in influenza virus infection. Upon influenza virus infection, DPF2 dysregulated IFN-β induction and expression of cytokines/chemokines and antiviral proteins. This study provides evidence that influenza virus utilizes DPF2 to escape host innate immunity.

scholarly journals Comprehensive profiling of translation initiation in influenza virus infected cells

2018 ◽  
Author(s):  
Heather M. Machkovech ◽  
Jesse D. Bloom ◽  
Arvind R. Subramaniam
Keyword(s):  
Influenza Virus ◽  
Virus Infection ◽  
Translation Initiation ◽  
Mammalian Cells ◽  
Transmembrane Domain ◽  
Influenza Virus Infection ◽  
Ribosome Profiling ◽  
Epithelial Cell Line ◽  
Human Lung Epithelial Cell ◽  
Evolutionary Forces

AbstractTranslation can initiate at alternate, non-canonical start codons in response to stressful stimuli in mammalian cells. Recent studies suggest that viral infection and anti-viral responses alter sites of translation initiation, and in some cases, lead to production of novel immune epitopes. Here we systematically investigate the extent and impact of alternate translation initiation in cells infected with influenza virus. We perform evolutionary analyses that suggest selection against non-canonical initiation at CUG codons in influenza virus lineages that have adapted to mammalian hosts. We then use ribosome profiling with the initiation inhibitor lactidomycin to experimentally delineate translation initiation sites in a human lung epithelial cell line infected with influenza virus. We identify several candidate sites of alternate initiation in influenza mRNAs, all of which occur at AUG codons that are downstream of canonical initiation codons. One of these candidate downstream start sites truncates 14 amino acids from the N-terminus of the N1 neuraminidase protein, resulting in loss of its cytoplasmic tail and a portion of the transmembrane domain. This truncated neuraminidase protein is expressed on the cell surface during influenza virus infection, is enzymatically active, and is conserved in most N1 viral lineages. Host transcripts induced by the anti-viral response are enriched for translation initiation at non-canonical start sites and non-AUG start codons. Together, our results systematically map the landscape of translation initiation during influenza virus infection, and shed light on the evolutionary forces shaping this landscape.

scholarly journals Mini viral RNAs act as innate immune agonists during influenza virus infection

2018 ◽  
Author(s):  
Aartjan J.W. te Velthuis ◽  
Joshua C. Long ◽  
David L.V. Bauer ◽  
Rebecca L.Y. Fan ◽  
Hui-Ling Yen ◽  
...  
Keyword(s):  
Influenza Virus ◽  
Virus Infection ◽  
Avian Influenza ◽  
Mammalian Cells ◽  
Systemic Disease ◽  
Influenza Virus Infection ◽  
Influenza Viruses ◽  
Innate Immune ◽  
Viral Rna ◽  
Viral Rnas

Influenza A virus infection usually causes a mild to moderately severe respiratory disease in humans. However, infection with the 1918 H1N1 pandemic or highly pathogenic avian influenza viruses (HPAIV) of the H5N1 subtype, can lead to viral pneumonia, systemic disease and death. The molecular processes that determine the outcome of influenza virus infection are multifactorial and involve a complex interplay between host, viral, and bacterial factors1. However, it is generally accepted that a strong innate immune dysregulation known as ‘cytokine storm’ contributes to the pathology of pandemic and avian influenza virus infections2–4. The RNA sensor Retinoic acid-inducible gene I (RIG-I) plays an important role in sensing viral infection and initiating a signalling cascade that leads to interferon (IFN) expression5. Here we show that short aberrant RNAs (mini viral RNAs; mvRNAs), produced by the viral RNA polymerase during the replication of the viral RNA genome, bind and activate the intracellular pathogen sensor RIG-I, and lead to the expression of interferon-β. We find that erroneous polymerase activity, dysregulation of viral RNA replication, or the presence of avian-specific amino acids underlie mvRNA generation and cytokine expression in mammalian cells and propose an intramolecular copy-choice mechanism for mvRNA generation. By deep-sequencing RNA samples from lungs of ferrets infected with influenza viruses we show that mvRNAs are generated during infection of animal models. We propose that mvRNAs act as main agonists of RIG-I during influenza virus infection and the ability of influenza virus strains to generate mvRNAs should be considered when assessing their virulence potential.

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