The role of the interaction of the influenza B virus NS1 protein with the cellular Brd2 protein

Park, Jang Won

22 October 2009

Influenza B virus is a major human pathogen causing highly contagious respiratory disease. It accounts for approximately ~30% of influenza virus infection per year. The effector domain of the NS1 protein of influenza B virus (NS1B protein), encompassing the carboxy terminal two thirds of the protein, suppresses interferon-β (IFN-β) synthesis in virus-infected cells by unknown mechanism(s). The induced IFN-β mediates innate immunity. To elucidate the mechanism by which the NS1B effector domain suppresses the production of IFN-β, we identified cellular proteins that interact with the NS1B effector domain. Two approaches were used. The approach that succeeded employed the transfection into cells of plasmids expressing the NS1B effector domain containing two affinity tags. After double affinity purification, co-purified cellular proteins were identified by mass spectrometry. We identified Brd2 as a cellular protein that interacts with the NS1B protein. We established that Brd2 specifically binds to the NS1B effector domain in vitro, in vivo, and in virus-infected cells. Serial mutagenesis experiments showed the phenylalanine at position 171 (F171) of the NS1B protein is essential for Brd2 binding. To determine the function of the interaction of Brd2 with the NS1B protein, we generated a recombinant virus encoding an NS1B protein in which F at position 171 was replaced by an alanine. The F171A mutant virus was attenuated, and unlike the wild-type virus, induced the synthesis of IFN-β mRNA. IRF3, a key transcription factor for transcription of the IFN-β gene, was activated in mutant virusinfected cells, but not in wild-type virus-infected cells. Transfection assays implicated the activation of the TBK1 kinase as the step in IRF3 activation that is induced in mutant virus-infected cells. We interpreted these results as showing that Brd2 binding to the NS1B protein is required for suppressing IRF3 activation and IFN-β induction. Attempts at further confirmation by depletion of endogenous Brd2 using RNA interference were not successful because of inefficient knock-down efficiency and nonspecific IFN-β induction. A further complication is that another bromodomain protein, Brd4, interacts with the NS1B protein and could compensate for depletion of Brd2. / text

Influenza B virus

NS1 protein

Effector domain

Brd2 protein

La protéine non-structurale NS1 du virus West Nile : étude fonctionnelle et cible potentielle de nouvelles molécules antivirales / Functional study of sNS1 viral protein during West Nile Virus infection and screening of novel molecules anti-WNV

Furnon, Wilhelm

18 January 2018

Parmi les virus émergents transmis par des moustiques (arbovirus), le genre flavivirus est fortement représenté avec les virus Dengue, Zika, et le virus West Nile (WNV). Le WNV est responsable de nombreux cas de maladies neuroinvasives sévères, parfois mortelles, chez l'humain et les chevaux. Ce virus représente donc un problème de santé publique humaine et animale. Il n'existe pour le moment aucun vaccin humain ni aucun traitement spécifique anti-WNV.Parmi les déterminants viraux essentiels à l'infection par les flavivirus, la glycoprotéine non-structurale NS1 possède des propriétés multifonctionnelles. La forme sNS1, sécrétée dans le milieu extracellulaire, est fortement impliquée dans la dérégulation du système immunitaire de l'hôte. Ces mécanismes participent à l'évasion du virus à la réponse antivirale et, paradoxalement, à la pathogenèse observée dans les formes sévères de la maladie. L'essentiel de ces données concernant le virus de la Dengue, nous souhaitions étudier les propriétés fonctionnelles, in vitro, de la protéine sNS1WNV au cours de l'infection de cellules épithéliales, gliales et neuronales de mammifères. En effet, la structure des protéines sNS1 de flavivirus étant très similaire, notre hypothèse suppose un rôle de sNS1WNV dans les infections neuroinvasives.Si la protéine sNS1WNV ne semble pas moduler les étapes de l'infection virale, elle est cependant à l'origine d'un remodelage du cytosquelette d'actine dans les cellules épithéliales. Elle est aussi impliquée dans l'activation de voies antivirales chez les cellules neuronales non infectées. D'autre part, en ciblant sNS1 et la protéine d'enveloppe E du WNV, nous avons pu isoler, par criblage de molécules aRep (protéines artificielles à motifs répétés), des ligands de haute affinité pour ces déterminants viraux. Ces nouvelles molécules, capables de se lier spécifiquement aux protéines sNS1 et E, ont le potentiel pour servir de base au développement de nouveaux outils de diagnostics et d'agents thérapeutiques antiviraux / Among emerging mosquito-borne viruses (arboviruses), flaviviruses like Dengue, Zika and West Nile virus (WNV) are very often involved in outbreaks. WNV causes several neuroinvasive diseases, which can be lethal, in humans and horses each year. This virus is a threat for both, human and animal public health. Furthermore, there is no human vaccine currently or any specific antiviral treatments against WNV.Among viral factors which are essential for flavivirus infection, the nonstructural glycoprotein NS1 is a multifunctional protein. The secreted form sNS1, is released in the extracellular medium from infected cells and is strongly involved in immune system dysregulation. The functions of sNS1 play roles in immune escape and, paradoxically, in pathogenesis which is observed in severe forms of the disease. Because most of this data are about Dengue Virus, we would like to study, in vitro, functional properties of the sNS1WNV during infection of epithelial, glial and neuronal mammalian cells. Based on the high sNS1 protein structure similarities among flaviviruses, our hypothesis suggests a role of sNS1WNV in neuroinvasive infections.The sNS1WNV protein doesn’t seem to modulate viral infection steps. However, it is involved in actin cytoskeleton remodeling in epithelial cells. sNS1WNV is also involved in the activation of antiviral response pathways in non-infected neuronal cells. On the other hand, by targeting sNS1 and envelope protein E of WNV, we performed a screening of aRep molecules (artificial proteins with alphahelicoïdal repeats) and isolated ligands with high affinity for these viral factors. Because this new type of molecules is able to specifically bind to sNS1 and E, they have potential to be used for the development of new diagnostic tools and antiviral therapeutic agents

Arbovirus

Flavivirus

West Nile

Protéine NS1

Pathogenèse

Protéine E

Criblage

Molécules alphaRep

Arbovirus

Flavivirus

West Nile Virus

NS1 protein

Pathogenesis

E protein

Screening

AlphaRep molecules

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