Your search keyword '"Digard P"' showing total 14 results

1. Individual influenza A virus mRNAs show differential dependence on cellular NXF1/TAP for their nuclear export

Author

Read, E. K. C., primary and Digard, P., additional

Published

2010

2. Genome packaging in influenza A virus

Author

Hutchinson, E. C., primary, von Kirchbach, J. C., additional, Gog, J. R., additional, and Digard, P., additional

Published

2009

3. Inhibition of the influenza virus RNA-dependent RNA polymerase by antisera directed against the carboxy-terminal region of the PB2 subunit

Author

Blok, V., primary, Cianci, C., additional, Tibbles, K. W., additional, Inglis, S. C., additional, Krystal, M., additional, and Digard, P., additional

Published

1996

4. An Analysis of the Biological Properties of Monoclonal Antibodies against Glycoprotein D of Herpes Simplex Virus and Identification of Amino Acid Substitutions that Confer Resistance to Neutralization

Author

Minson, A. C., primary, Hodgman, T. C., additional, Digard, P., additional, Hancock, D. C., additional, Bell, S. E., additional, and Buckmaster, E. A., additional

Published

1986

5. PA-X is an avian virulence factor in H9N2 avian influenza virus.

Author

Clements AL, Peacock TP, Sealy JE, Lee HM, Hussain S, Sadeyen JR, Shelton H, Digard P, and Iqbal M

Subjects

Animals, Cell Line, Chickens, Cytokines genetics, Cytokines immunology, Humans, Influenza A Virus, H9N2 Subtype genetics, Influenza A Virus, H9N2 Subtype pathogenicity, Influenza in Birds genetics, Influenza in Birds immunology, Influenza, Human genetics, Influenza, Human immunology, Lung immunology, Lung virology, Mice, Repressor Proteins genetics, Viral Nonstructural Proteins genetics, Virulence Factors genetics, Virus Replication, Virus Shedding, Influenza A Virus, H9N2 Subtype metabolism, Influenza in Birds virology, Influenza, Human virology, Repressor Proteins metabolism, Viral Nonstructural Proteins metabolism, Virulence Factors metabolism

Abstract

Influenza A viruses encode several accessory proteins that have host- and strain-specific effects on virulence and replication. The accessory protein PA-X is expressed due to a ribosomal frameshift during translation of the PA gene. Depending on the particular combination of virus strain and host species, PA-X has been described as either acting to reduce or increase virulence and/or virus replication. In this study, we set out to investigate the role PA-X plays in H9N2 avian influenza viruses, focusing on the natural avian host, chickens. We found that the G1 lineage A/chicken/Pakistan/UDL-01/2008 (H9N2) PA-X induced robust host shutoff in both mammalian and avian cells and increased virus replication in mammalian, but not avian cells. We further showed that PA-X affected embryonic lethality in ovo and led to more rapid viral shedding and widespread organ dissemination in vivo in chickens. Overall, we conclude PA-X may act as a virulence factor for H9N2 viruses in chickens, allowing faster replication and wider organ tropism.

Published

2021

6. Segment 2 from influenza A(H1N1) 2009 pandemic viruses confers temperature-sensitive haemagglutinin yield on candidate vaccine virus growth in eggs that can be epistatically complemented by PB2 701D.

Author

Hussain S, Turnbull ML, Pinto RM, McCauley JW, Engelhardt OG, and Digard P

Subjects

Animals, Chick Embryo, Hemagglutinin Glycoproteins, Influenza Virus genetics, Humans, Influenza A Virus, H1N1 Subtype genetics, Influenza A Virus, H1N1 Subtype metabolism, Influenza Vaccines genetics, Influenza Vaccines metabolism, Reassortant Viruses genetics, Reassortant Viruses growth & development, Reassortant Viruses metabolism, Temperature, Viral Proteins metabolism, Epistasis, Genetic, Hemagglutinin Glycoproteins, Influenza Virus metabolism, Influenza A Virus, H1N1 Subtype growth & development, Influenza, Human virology, Viral Proteins genetics

Abstract

Candidate vaccine viruses (CVVs) for seasonal influenza A virus are made by reassortment of the antigenic virus with an egg-adapted strain, typically A/Puerto Rico/8/34 (PR8). Many 2009 A(H1N1) pandemic (pdm09) high-growth reassortants (HGRs) selected this way contain pdm09 segment 2 in addition to the antigenic genes. To investigate this, we made CVV mimics by reverse genetics (RG) that were either 6 : 2 or 5 : 3 reassortants between PR8 and two pdm09 strains, A/California/7/2009 (Cal7) and A/England/195/2009, differing in the source of segment 2. The 5 : 3 viruses replicated better in MDCK-SIAT1 cells than the 6 : 2 viruses, but the 6 : 2 CVVs gave higher haemagglutinin (HA) antigen yields from eggs. This unexpected phenomenon reflected temperature sensitivity conferred by pdm09 segment 2, as the egg HA yields of the 5 : 3 viruses improved substantially when viruses were grown at 35 °C compared with 37.5 °C, whereas the 6 : 2 virus yields did not. However, the authentic 5 : 3 pdm09 HGRs, X-179A and X-181, were not markedly temperature sensitive despite their PB1 sequences being identical to that of Cal7, suggesting compensatory mutations elsewhere in the genome. Sequence comparisons of the PR8-derived backbone genes identified polymorphisms in PB2, NP, NS1 and NS2. Of these, PB2 N701D affected the temperature dependence of viral transcription and, furthermore, improved and drastically reduced the temperature sensitivity of the HA yield from the 5 : 3 CVV mimic. We conclude that the HA yield of pdm09 CVVs can be affected by an epistatic interaction between PR8 PB2 and pdm09 PB1, but that this can be minimized by ensuring that the backbones used for vaccine manufacture in eggs contain PB2 701D.

Published

2019

7. The cellular localization of avian influenza virus PB1-F2 protein alters the magnitude of IFN2 promoter and NFκB-dependent promoter antagonism in chicken cells.

Author

James J, Smith N, Ross C, Iqbal M, Goodbourn S, Digard P, Barclay WS, and Shelton H

Subjects

Animals, Chickens, Influenza A Virus, H5N1 Subtype genetics, Influenza A Virus, H9N2 Subtype genetics, Influenza in Birds genetics, Influenza in Birds virology, Interferon-beta immunology, NF-kappa B immunology, Poultry Diseases immunology, Poultry Diseases virology, Promoter Regions, Genetic, Viral Proteins genetics, Influenza A Virus, H5N1 Subtype metabolism, Influenza A Virus, H9N2 Subtype metabolism, Influenza in Birds immunology, Interferon-beta genetics, NF-kappa B genetics, Poultry Diseases genetics, Viral Proteins metabolism

Abstract

The accessory protein, PB1-F2, of influenza A virus (IAV) functions in a chicken host to prolong infectious virus shedding and thus the transmission window. Here we show that this delay in virus clearance by PB1-F2 in chickens is accompanied by reduced transcript levels of type 1 interferon (IFN)-induced genes and NFκB-activated pro-inflammation cytokines. In vitro, two avian influenza isolate-derived PB1-F2 proteins, H9N2 UDL01 and H5N1 5092, exhibited the same antagonism of the IFN and pro-inflammation induction pathways seen in vivo, but to different extents. The two PB1-F2 proteins had different cellular localization in chicken cells, with H5N1 5092 being predominantly mitochondrial-associated and H9N2 UDL being cytoplasmic but not mitochondrial-localized. We hypothesized that PB1-F2 localization might influence the functionality of the protein during infection and that the protein sequence could alter cellular localization. We demonstrated that the sequence of the C-terminus of PB1-F2 determined cytoplasmic localization in chicken cells and this was linked with protein instability. Mitochondrial localization of PB1-F2 resulted in reduced antagonism of an NFκB-dependent promoter. In parallel, mitochondrial localization of PB1-F2 increased the potency of chicken IFN 2 induction antagonism. We suggest that mitochondrial localization of PB1-F2 restricts interaction with cytoplasmic-located IKKβ, reducing NFκB-responsive promoter antagonism, but enhances antagonism of the IFN2 promoter through interaction with the mitochondrial adaptor MAVS. Our study highlights the differential mechanisms by which IAV PB1-F2 protein can dampen the avian host innate signalling response.

Published

2019

8. Permissive and restricted virus infection of murine embryonic stem cells.

Author

Wash R, Calabressi S, Franz S, Griffiths SJ, Goulding D, Tan EP, Wise H, Digard P, Haas J, Efstathiou S, and Kellam P

Subjects

Animals, Cell Line, Cricetinae, DNA Replication genetics, Dogs, Embryonic Stem Cells metabolism, HeLa Cells, Herpes Simplex genetics, Herpes Simplex metabolism, Herpesvirus 1, Human genetics, Herpesvirus 1, Human metabolism, Herpesvirus 1, Human physiology, Host-Pathogen Interactions, Humans, Influenza A virus genetics, Influenza A virus metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Orthomyxoviridae Infections metabolism, Orthomyxoviridae Infections virology, RNA, Small Interfering genetics, Transcription, Genetic, Viral Proteins genetics, Viral Proteins metabolism, Embryonic Stem Cells physiology, Embryonic Stem Cells virology, Influenza A virus physiology, Orthomyxoviridae Infections genetics, Virus Replication genetics

Abstract

Recent RNA interference (RNAi) studies have identified many host proteins that modulate virus infection, but small interfering RNA 'off-target' effects and the use of transformed cell lines limit their conclusiveness. As murine embryonic stem (mES) cells can be genetically modified and resources exist where many and eventually all known mouse genes are insertionally inactivated, it was reasoned that mES cells would provide a useful alternative to RNAi screens. Beyond allowing investigation of host-pathogen interactions in vitro, mES cells have the potential to differentiate into other primary cell types, as well as being used to generate knockout mice for in vivo studies. However, mES cells are poorly characterized for virus infection. To investigate whether ES cells can be used to explore host-virus interactions, this study characterized the responses of mES cells following infection by herpes simplex virus type 1 (HSV-1) and influenza A virus. HSV-1 replicated lytically in mES cells, although mES cells were less permissive than most other cell types tested. Influenza virus was able to enter mES cells and express some viral proteins, but the replication cycle was incomplete and no infectious virus was produced. Knockdown of the host protein AHCYL1 in mES cells reduced HSV-1 replication, showing the potential for using mES cells to study host-virus interactions. Transcriptional profiling, however, indicated the lack of an efficient innate immune response in these cells. mES cells may thus be useful to identify host proteins that play a role in virus replication, but they are not suitable to determine factors that are involved in innate host defence.

Published

2012

9. Release of filamentous and spherical influenza A virus is not restricted by tetherin.

Author

Bruce EA, Abbink TE, Wise HM, Rollason R, Galao RP, Banting G, Neil SJ, and Digard P

Subjects

Animals, Cell Line, Cell Membrane chemistry, GPI-Linked Proteins metabolism, Hemagglutinin Glycoproteins, Influenza Virus metabolism, Humans, Influenza A virus growth & development, Microscopy, Confocal, Microscopy, Electron, Scanning, Viral Load, Antigens, CD metabolism, Host-Pathogen Interactions, Influenza A virus physiology, Virus Release

Abstract

The cellular protein tetherin is thought to act as a 'leash' that anchors many enveloped viruses to the plasma membrane and prevents their release. We found that replication of multiple strains of influenza A virus was generally insensitive to alteration of tetherin levels, as assessed by output titre or scanning electron microscopy of cell-associated virions. This included human, swine, avian and equine isolates, strains that form filamentous or spherical particles and viruses that lack the M2 or NS1 proteins. Levels of cell-surface tetherin were not reduced by influenza infection, but tetherin and the viral haemagglutinin co-localized on the plasma membrane. However, tetherin could not be detected in filamentous virions, suggesting that influenza may possess a mechanism to exclude it from virions. Overall, if influenza does encode a specific antagonist of tetherin, it is not M2 or NS1 and we find no evidence for a role in host range specificity.

Published

2012

10. Influence of PB2 host-range determinants on the intranuclear mobility of the influenza A virus polymerase.

Author

Foeglein Á, Loucaides EM, Mura M, Wise HM, Barclay WS, and Digard P

Subjects

Amino Acid Motifs, Amino Acid Sequence, Animals, Birds, Cell Line, Humans, Influenza A Virus, H1N1 Subtype, Influenza A virus chemistry, Influenza A virus genetics, Influenza A virus physiology, Molecular Sequence Data, Protein Transport, Quail, RNA-Dependent RNA Polymerase chemistry, RNA-Dependent RNA Polymerase genetics, Viral Proteins chemistry, Viral Proteins genetics, Host Specificity, Influenza A virus enzymology, Influenza in Birds virology, Influenza, Human virology, RNA-Dependent RNA Polymerase metabolism, Viral Proteins metabolism

Abstract

Avian influenza A viruses often do not propagate efficiently in mammalian cells. The viral polymerase protein PB2 is important for this host restriction, with amino-acid polymorphisms at residue 627 and other positions acting as 'signatures' of avian- or human-adapted viruses. Restriction is hypothesized to result from differential interactions (either positive or inhibitory) with unidentified cellular factors. We applied fluorescence recovery after photobleaching (FRAP) to investigate the mobility of the viral polymerase in the cell nucleus using A/PR/8/34 and A/Turkey/England/50-92/91 as model strains. As expected, transcriptional activity of a polymerase with the avian PB2 protein was strongly dependent on the identity of residue 627 in human but not avian cells, and this correlated with significantly slower diffusion of the inactive polymerase in human but not avian nuclei. In contrast, the activity and mobility of the PR8 polymerase was affected much less by residue 627. Sequence comparison followed by mutagenic analyses identified residues at known host-range-specific positions 271, 588 and 701 as well as a novel determinant at position 636 as contributors to host-specific activity of both PR8 and Turkey PB2 proteins. Furthermore, the correlation between poor transcriptional activity and slow diffusional mobility was maintained. However, activity did not obligatorily correlate with predicted surface charge of the 627 domain. Overall, our data support the hypothesis of a host nuclear factor that interacts with the viral polymerase and modulates its activity. While we cannot distinguish between positive and inhibitory effects, the data have implications for how such factors might operate.

Published

2011

11. Genome packaging in influenza A virus.

Author

Hutchinson EC, von Kirchbach JC, Gog JR, and Digard P

Subjects

Animals, Humans, Influenza A virus genetics, Influenza, Human virology, Orthomyxoviridae Infections veterinary, Orthomyxoviridae Infections virology, RNA, Viral genetics, RNA, Viral metabolism, Virion genetics, Genome, Viral, Influenza A virus physiology, Virion physiology, Virus Assembly

Abstract

The negative-sense RNA genome of influenza A virus is composed of eight segments, which encode 12 proteins between them. At the final stage of viral assembly, these genomic virion (v)RNAs are incorporated into the virion as it buds from the apical plasma membrane of the cell. Genome segmentation confers evolutionary advantages on the virus, but also poses a problem during virion assembly as at least one copy of each of the eight segments is required to produce a fully infectious virus particle. Historically, arguments have been presented in favour of a specific packaging mechanism that ensures incorporation of a full genome complement, as well as for an alternative model in which segments are chosen at random but packaged in sufficient numbers to ensure that a reasonable proportion of virions are viable. The question has seen a resurgence of interest in recent years leading to a consensus that the vast majority of virions contain no more than eight segments and that a specific mechanism does indeed function to select one copy of each vRNA. This review summarizes work leading to this conclusion. In addition, we describe recent progress in identifying the specific packaging signals and discuss likely mechanisms by which these RNA elements might operate.

Published

2010

12. Identification of the domains of the influenza A virus M1 matrix protein required for NP binding, oligomerization and incorporation into virions.

Author

Noton SL, Medcalf E, Fisher D, Mullin AE, Elton D, and Digard P

Subjects

Animals, Cell Line, Dimerization, Dogs, Escherichia coli metabolism, Membrane Proteins metabolism, Nucleoproteins biosynthesis, Nucleoproteins genetics, Peptides metabolism, Protein Binding, Recombinant Proteins metabolism, Ribonucleoproteins metabolism, Viral Fusion Proteins biosynthesis, Viral Fusion Proteins genetics, Viral Fusion Proteins metabolism, Viral Matrix Proteins biosynthesis, Viral Matrix Proteins chemistry, Viral Matrix Proteins genetics, Virus Replication, Influenza A virus physiology, Nucleoproteins metabolism, Protein Structure, Tertiary physiology, Viral Matrix Proteins metabolism, Virion metabolism

Abstract

The matrix (M1) protein of influenza A virus is a multifunctional protein that plays essential structural and functional roles in the virus life cycle. It drives virus budding and is the major protein component of the virion, where it forms an intermediate layer between the viral envelope and integral membrane proteins and the genomic ribonucleoproteins (RNPs). It also helps to control the intracellular trafficking of RNPs. These roles are mediated primarily via protein-protein interactions with viral and possibly cellular proteins. Here, the regions of M1 involved in binding the viral RNPs and in mediating homo-oligomerization are identified. In vitro, by using recombinant proteins, it was found that the middle domain of M1 was responsible for binding NP and that this interaction did not require RNA. Similarly, only M1 polypeptides containing the middle domain were able to bind to RNP-M1 complexes isolated from purified virus. When M1 self-association was examined, all three domains of the protein participated in homo-oligomerization although, again, the middle domain was dominant and self-associated efficiently in the absence of the N- and C-terminal domains. However, when the individual fragments of M1 were tagged with green fluorescent protein and expressed in virus-infected cells, microscopy of filamentous particles showed that only full-length M1 was incorporated into budding virions. It is concluded that the middle domain of M1 is primarily responsible for binding NP and self-association, but that additional interactions are required for efficient incorporation of M1 into virus particles.

Published

2007

13. Increased amounts of the influenza virus nucleoprotein do not promote higher levels of viral genome replication.

Author

Mullin AE, Dalton RM, Amorim MJ, Elton D, and Digard P

Subjects

Cell Line, Genome, Viral, Humans, Nucleocapsid Proteins, Ribonucleoproteins physiology, Nucleoproteins physiology, RNA, Viral biosynthesis, RNA-Binding Proteins physiology, Viral Core Proteins physiology

Abstract

Influenza virus genome replication requires the virus-encoded nucleoprotein (NP), partly because it is necessary to encapsidate the viral genomic RNA (vRNA) and antigenomic cRNA segments into ribonucleoproteins (RNPs). However, there is also evidence that NP actively regulates viral RNA synthesis and there is a long-standing hypothesis that increased concentrations of NP in the cell are responsible for a switch from genome transcription to replication. Here, this hypothesis is tested in a recombinant setting and in the context of virus infection. In a plasmid-based system for reconstituting active viral RNPs in cells, titration of increasing amounts of NP did not promote higher levels of genome replication relative to transcription, but in fact caused the opposite effect. An approximately fourfold reduction in the ratio of genomic and antigenomic RNAs to mRNA was seen across an 80-fold range of NP plasmid concentrations. When cells were transfected with the same amounts of NP plasmid to establish a concentration gradient of NP prior to virus superinfection, no change in the ratio of cRNA to mRNA was seen for segments 5 and 7, or for the ratio of segment 5 vRNA to mRNA. A slight reduction in the ratio of segment 7 vRNA to mRNA was seen. These findings do not support the simple hypothesis that increased intracellular concentrations of NP promote influenza virus genome replication.

Published

2004

14. The influenza virus nucleoprotein: a multifunctional RNA-binding protein pivotal to virus replication.

Author

Portela A and Digard P

Subjects

Actins physiology, Biological Transport, Karyopherins physiology, Nucleocapsid Proteins, RNA metabolism, RNA, Viral biosynthesis, Ribonucleoproteins metabolism, Viral Core Proteins chemistry, Nucleoproteins, Orthomyxoviridae physiology, RNA-Binding Proteins physiology, Viral Core Proteins physiology, Virus Replication

Abstract

All viruses with negative-sense RNA genomes encode a single-strand RNA-binding nucleoprotein (NP). The primary function of NP is to encapsidate the virus genome for the purposes of RNA transcription, replication and packaging. The purpose of this review is to illustrate using the influenza virus NP as a well-studied example that the molecule is much more than a structural RNA-binding protein, but also functions as a key adapter molecule between virus and host cell processes. It does so through the ability to interact with a wide variety of viral and cellular macromolecules, including RNA, itself, two subunits of the viral RNA-dependent RNA polymerase and the viral matrix protein. NP also interacts with cellular polypeptides, including actin, components of the nuclear import and export apparatus and a nuclear RNA helicase. The evidence for the existence of each of these activities and their possible roles in transcription, replication and intracellular trafficking of the virus genome is considered.

Published

2002