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Influenza virus ribonucleoprotein complex formation occurs in the nucleolus

Susumu Miyamoto1, Masahiro Nakano1, Takeshi Morikawa1, Ai Hirabayashi1, Tamura R1, Yoko Fujita1, Naoki Hirose1, Yukiko Muramoto1, Takeshi Noda1 
Kyoto University1
24 Feb 2021-bioRxiv (Cold Spring Harbor Laboratory)-
TL;DR: In this article, the subnuclear site of double-helical ribonucleoprotein complex (vRNP) formation in influenza virus was investigated and it was found that all vRNP components were colocalized in the nucleolus of virus-infected cells at early stage of infection.
Abstract: Influenza A virus double-helical ribonucleoprotein complex (vRNP) performs transcription and replication of viral genomic RNA (vRNA). Unlike most RNA viruses, vRNP formation accompanied by vRNA replication is carried out in the nucleus of virus-infected cell. However, the precise subnuclear site remains unknown. Here, we report the subnuclear site of vRNP formation in influenza virus. We found that all vRNP components were colocalized in the nucleolus of virus-infected cells at early stage of infection. Mutational analysis showed that nucleolar localization of viral nucleoprotein, a major vRNP component, is critical for functional double-helical vRNP formation. Furthermore, nucleolar disruption of virus-infected cells inhibited vRNP component assembly into double-helical vRNPs, resulting in decreased vRNA transcription and replication. Collectively, our findings demonstrate that the vRNA replication-coupled vRNP formation occurs in the nucleolus, demonstrating the importance of the nucleolus for influenza virus life cycle.

Summary (4 min read)

Jump to: [Main][Result Nucleolar localization of vRNP components][Importance of nucleolar NP localization for functional vRNP formation][Impact of nucleolar disruption on functional vRNP formation][Discussion][Plasmid construction][Immunofluorescence][Protease treatment][Fluorescence in situ hybridisation (FISH)][Western blotting][Cell viability][vRNP purification][In vitro transcription of vRNPs][High-speed atomic force microscopy (HS-AFM)][Immuno-electron microscopy][RT-PCR][RT-qPCR][Strand-specific RT-qPCR] and [Subcellular fractionation]

Main

  • Accordingly, influenza A virus transcription, replication, and vRNP formation heavily rely on host nuclear machineries.
  • Upon initiation of vRNA transcription, viral polymerase complex in the vRNP binds to carboxy-terminal domain of host RNA polymerase II (Pol II) 7 .
  • Since these host proteins are localized in different intranuclear domains, subnuclear site of vRNA replication and vRNP formation remains unidentified.

Result Nucleolar localization of vRNP components

  • Given that the nucleolus is a site of vRNP formation, de novo synthesized vRNP components (NP, PB2, PB1, PA, and vRNA) should simultaneously exist in the nucleolus of virus-infected cell.
  • To examine their localization in virus-infected cells, Madin-Darby Canine Kidney (MDCK) cells were infected with influenza A virus and fixed over time.
  • Immunostaining with an anti-NP antibody showed that NP was co-localized with nucleolin/C23, a nucleolar marker, 5-7 h post-infections (hpi) .
  • In contrast, although PB2 subunits were localized in the GC regions, they were mainly localized in periphery, but not central region, of the nucleolus .
  • These results suggest that the vRNP components are assembled into vRNP in the GC region of the nucleolar periphery.

Importance of nucleolar NP localization for functional vRNP formation

  • To investigate the importance of NP nucleolar localization for the vRNP formation, the authors constructed mutant vRNPs using two NoLS-mutant NPs: NP NoLSmut with alanine substitutions in the NoLS localizes only in the nucleoplasm and a reverse mutant NoLS-NP NoLSmut , with an intact NoLS fused to the amino-terminus of NP NoLSmut that causes its nucleolar localization 18 .
  • Then, the cells were subjected to immunoprecipitation using anti-FLAG antibody, and the precipitates were assessed by western blotting and RT-PCR .
  • Furthermore, full-length HA vRNA was barely detected in the precipitate, and the immunoprecipitated vRNPs did not produce HA mRNA , indicating that the NP NoLSmut was not properly assembled into functional vRNPs, although heterotrimeric viral polymerase subunit was assembled.
  • Intriguingly, NoLS-NP NoLSmut , PB1, and PA were adequately coprecipitated with PB2, from which full-length HA vRNA was detected .
  • Taken together, these results indicate that nucleolar localization of NP is indispensable for functional vRNP formation.

Impact of nucleolar disruption on functional vRNP formation

  • Considering the necessity of nucleolar NP localization for proper vRNP formation, nucleolar structure disruption would heavily impact the vRNP component assembly.
  • Actinomycin D, which inhibits both Pol I and Pol II activities, was used as control.
  • CX5461 treatment modestly decreased the amount of immunoprecipitated NP as well as PB1 and PA subunits in these cells, although viral protein expression levels were comparable, or marginally lower, compared to those in control cells , suggesting that nucleolar disruption impacted the vRNP component assembly.
  • Thus, these results demonstrate that the nucleolus is required for proper assembly of the vRNP components into functional double-helical vRNPs.

Discussion

  • The authors showed that the nucleolus is the site for formation of functional vRNPs with double-helical structure.
  • Inhibition of nucleolar NP localization and nucleolar structure disruption affected vRNP component assembly, resulting in defective vRNP formation.
  • Thus, interaction between viral polymerase and NP is likely involved in its nucleolar import and subsequent vRNP formation.
  • Khatchikian et al. reported that host 28S rRNA-derived 54 nucleotides are inserted into the HA vRNA during viral replication via genetic recombination 35 .
  • Moreover, the authors detected not only vRNA but also anti-genomic RNA in the nucleolus of virus-infected cells, supporting that the nucleolus is the site of vRNA replication and vRNP formation.

Plasmid construction

  • PCAGGS/NP NoLSmut and pCAGGS/NoLS-NP NoLSmut were constructed using inverse PCR 38 with sequences similar to those previously reported (pCAGGS/NP-NLS2mut and pCAGGS/NLS2-NP-NLS2mut, respectively) 18 .
  • To generate pCAGGS/PB2-FLAG, the PB2 ORF and FLAG were linked with a linker (AAA).
  • PPol I/PB2-FLAG was constructed by inserting the PB2-FLAG ORF with stop codon into a truncated pPol I/PB2 plasmid with 3′ non-coding region and additional 143 nucleotides of 5′ terminal coding and non-coding regions 39 .

Immunofluorescence

  • Cells were plated in 8-well chamber slides (Matsunami, Japan) coated with rat collagen I (Corning, NY USA).
  • Infected or transfected cells were fixed in 4% paraformaldehyde (PFA) in phosphate buffer (PB) (Nacalai Tesque, Japan) for 10 min and then permeabilized with 0.5% Triton-X in PBS for 5 min.
  • The cells were blocked with Blocking One (Nacalai Tesque) for 30 min followed by incubation with primary antibodies overnight at 4 °C and secondary antibodies for 1 h at room temperature.
  • For nuclei and rRNA staining, cells were treated with Hoechst 33342 (Thermo Fisher Scientific) and Nucleolus Bright Red (Dojindo, Japan), respectively, for 10 min.
  • Section images were recorded using DeltaVision Elite (GE healthcare) with a 60× oil objective, deconvolved and projected using 'Quick Projection' tool by softWoRx (GE Healthcare).

Protease treatment

  • As the optimal condition for protease treatment depends on the protease type, lot, and cell strain 20 , the authors recommend verifying the protease concentration and incubation time.
  • After permeabilization, the cells were washed twice in cold-PBS on ice and placed in cold 5 µg/mL TPCK-Trypsin in PBS.
  • Thereafter, the cells were washed in PBS and blocked as described above.

Fluorescence in situ hybridisation (FISH)

  • Briefly, probes were transcribed in vitro using digoxigenin (DIG)-11-UTP and RiboMAX Large Scale RNA Production System-T7 (Promega, WI USA).
  • The template of positive-and negative-sense PB2 genome segment (~300 bp) was PCR amplified using pPol I/PB2.
  • The infected cells were fixed with 4% PFA in PB for 10 min and permeabilized with 0.5% Triton X-100 for 5 min at room temperature.
  • Cells were then blocked with prehybridization buffer (50% formamide [Fujifilm], 2× SSC, 5× Denhardt's solution [Fujifilm], 20 μg/mL salmon sperm DNA [BioDynamics Laboratory, Japan]) for 1 h at room temperature and then incubated with 200 ng/mL of DIG-labelled RNA probe diluted in prehybridization buffer overnight at 60 °C on a shaker.

Western blotting

  • Briefly, cells or samples described below were dissolved with 2× Tris-Glycine SDS Sample Buffer (Thermo Fisher Scientific), boiled for 5 min in absence of a reducing agent, and subjected to SDS-PAGE.
  • Proteins were electroblotted onto Immobilon-P transfer membranes .
  • The membranes were blocked with Blocking One for 30 min at room temperature and then incubated with primary antibodies overnight at 4 °C.
  • After incubation with HRP-conjugated secondary antibodies for 1 h at room temperature, the blots were developed using Chemi-Lumi One Super (Nacalai Tesque).

Cell viability

  • Cell viability was assessed with CellTiter-Glo Luminescent Cell Viability Assay according to the manufacturer's instructions.
  • Briefly, CellTiter-Glo reagent (equal in volume to the culture medium) was added to A549 cells.
  • Plates were shaken on a plate shaker for 2 min to induce cell lysis, incubated at room temperature for 10 min, and subjected to luminescence measurement.

vRNP purification

  • To prepare virion-derived vRNPs, MDCK cells were infected with the virus and incubated at 37 °C for two days.
  • Virions in the supernatants were purified by ultracentrifugation through a 30% (w/w) sucrose cushion.
  • Each fraction was electrophoresed with SDS-polyacrylamide gel and immunoblotted with an anti-NP antibody .
  • NP-enriched fractions 7 and 8 were used for vRNP observations.

In vitro transcription of vRNPs

  • RNA was purified using RNeasy Mini kit, mixed with equal volume of 2× RNA Loading Dye (New England Biolabs), heated at 90 °C for 2 min, and immediately chilled on ice.
  • For preparation of vRNA markers, all eight vRNA segments of the influenza virus were transcribed using 0.25 μCi/μL [α-32 P] UTP and RiboMAX Large Scale RNA Production System-T7 as described above.
  • The transcribed RNAs were purified and mixed before electrophoresis.

High-speed atomic force microscopy (HS-AFM)

  • The samples were prepared in a microcentrifuge tube, dropped onto freshly cleaved mica without any surface modification, and incubated for 1-5 min at room temperature (~24°C).
  • Images were taken at a 2 images/sec rate using cantilevers (BL-AC10DS, Olympus, Japan) with a 0.1 N/m spring constant and a resonance frequency in water of 0.6 MHz.
  • To increase the resolution, the electron-beam deposited tips were fabricated using phenol or ferrocene powder 45 .
  • A low-pass filter and a flattening filter were applied to individual images to remove spike noise and flatten the xy-plane, respectively.
  • Rod-like and helical structures with a uniform height of 9.0 ± 1.5 nm were defined as helical vRNPs.

Immuno-electron microscopy

  • Purified vRNPs were adsorbed onto carbon-coated nickel grids and fixed with 2% PFA for 5 min.
  • After washing, the grids were incubated with 6-nm gold conjugated anti-mouse or anti-rabbit antibodies for 1 h at room temperature.
  • The images were acquired with an HT7700 (Hitachi High-Tech Corporation, Japan).
  • For thin-section preparations, infected and mock-infected MDCK cells were fixed with 1.5% PFA and 0.025% glutaraldehyde in 0.1 M PB for 1 h.
  • Ultrathin sections (80 nm) were cut with Leica EM UC7 (Leica, Germany) and collected on a nickel grid.

RT-PCR

  • Total RNAs were extracted using an RNeasy Mini Kit with on-column DNase digestion .
  • Ten nanograms of the extracted RNA samples were reverse-transcribed using a Uni-12 primer (5′-AGCRAAAGCAGG-3′) and Superscript III reverse transcriptase (Thermo Fisher Scientific).
  • Ten-fold diluted cDNAs were PCR amplified using KOD FX (Toyobo, Japan) and 0.25 μM HA segment-specific primers according to manufacturer's protocol.
  • The PCR products were electrophoresed on 1.0% agarose gels containing 0.01% (w/v) ethidium bromide in 0.5× TBE.

RT-qPCR

  • Two-hundred nanograms of total RNAs were reverse-transcribed using Random primer 6 (New England Biolabs) and Superscript III reverse transcriptase.
  • The relative expression levels of target genes were normalized to that of GAPDH.
  • A primer set for pre-rRNA, described previously 47 , was used.

Strand-specific RT-qPCR

  • Briefly, total RNA was extracted from cells using an RNeasy Mini Kit.
  • CDNAs complementary to the three types of HA genome were synthesized with tagged primers at the 5′ end.

Subcellular fractionation

  • Total protein concentrations were measured using Pierce BCA Protein Assay Kit (Thermo Fisher Scientific) and adjusted to approximately 0.5 µg/mL.
  • The samples (~0.5 µg) were subjected to western blotting.

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Figures (2)

Content maybe subject to copyright    Report

1
Influenza virus ribonucleoprotein complex formation occurs
1
in the nucleolus
2
3
Sho Miyamoto
1#
, Masahiro Nakano
1,2,3
, Takeshi Morikawa
1
, Ai Hirabayashi
1,2,3
, Ryoma
4
Tamura
1,2
, Yoko Fujita
1,2,3
, Nanami Hirose
1,2,3
, Yukiko Muramoto
1,2,3
, Takeshi Noda
1,2,3*
.
5
6
1
Laboratory of Ultrastructural Virology, Institute for Frontier Life and Medical
7
Sciences, Kyoto University, 53 Shogoin Kawahara-cho, Sakyo-ku, Kyoto 606-8507,
8
Japan
9
2
Laboratory of Ultrastructural Virology, Graduate School of Biostudies, Kyoto
10
University, 53 Shogoin Kawahara-cho, Sakyo-ku, Kyoto 606-8507, Japan
11
3
CREST, Japan Science and Technology Agency, 4-1-8 Honcho, Kawaguchi, Saitama
12
332-0012, Japan
13
#
present address: Department of Pathology, National Institute of Infectious Diseases,
14
Toyama 1-23-1, Shinjuku-ku, Tokyo 162-8640, Japan
15
*correspondence to: t-noda@infront.kyoto-u.ac.jp
16
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
2
17
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
3
Abstract
18
Influenza A virus double-helical ribonucleoprotein complex (vRNP) performs
19
transcription and replication of viral genomic RNA (vRNA). Unlike most RNA
20
viruses, vRNP formation accompanied by vRNA replication is carried out in the
21
nucleus of virus-infected cell. However, the precise subnuclear site remains
22
unknown. Here, we report the subnuclear site of vRNP formation in influenza
23
virus. We found that all vRNP components were colocalized in the nucleolus of
24
virus-infected cells at early stage of infection. Mutational analysis showed that
25
nucleolar localization of viral nucleoprotein, a major vRNP component, is critical
26
for functional double-helical vRNP formation. Furthermore, nucleolar disruption
27
of virus-infected cells inhibited vRNP component assembly into double-helical
28
vRNPs, resulting in decreased vRNA transcription and replication. Collectively,
29
our findings demonstrate that the vRNA replication-coupled vRNP formation
30
occurs in the nucleolus, demonstrating the importance of the nucleolus for
31
influenza virus life cycle.
32
33
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
4
Main
34
Influenza A virus, belonging to the Orthomyxoviridae family, possesses
35
eight-segmented, single-stranded, negative-sense RNA as its genome. Each viral
36
genomic RNA (vRNA) segment exists as a ribonucleoprotein complex (vRNP)
37
associated with multiple nucleoproteins (NPs) and a heterotrimeric RNA-dependent
38
RNA polymerase complex composed of PB2, PB1, and PA subunits
1
. The vRNPs,
39
which are flexible double-stranded helices (width, ~10 nm; length, 30–120 nm)
2
, are
40
responsible for transcription and replication of the vRNAs. On transcription, vRNA is
41
transcribed into 5′-capped and 3′-polyadenylated mRNA by the polymerase complex in
42
a primer-dependent manner. During genome replication, the vRNA is copied into
43
complementary RNA (cRNA) replicative intermediate by cis-acting viral polymerase
44
complex, and the cRNA acts as a template for generating more vRNAs, with
45
involvement of a trans-activating/trans-acting viral polymerase complex
3,4
. These
46
replication processes are concomitant with ribonucleoprotein complex assembly; the 5′
47
terminals of the nascent vRNA and cRNA are associated with a newly synthesized viral
48
polymerase complex that is sequentially coated with multiple NPs and assembled into
49
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
5
double-helical vRNPs and cRNPs, respectively
5
.
50
Unlike most RNA viruses, influenza A virus transcribes and replicates its
51
genome in the nucleus of virus-infected cells
6
. Accordingly, influenza A virus
52
transcription, replication, and vRNP formation heavily rely on host nuclear machineries.
53
Upon initiation of vRNA transcription, viral polymerase complex in the vRNP binds to
54
carboxy-terminal domain of host RNA polymerase II (Pol II)
7
. Then, the PB2 subunit
55
binds to 5′-cap structure of host pre-mRNAs or small nuclear/nucleolar RNAs
8,9
, and
56
the PA subunit cleaves and snatches the 5′-capped fragment for use as a primer
10-12
. The
57
requirement of Pol II for initiation of viral mRNA synthesis indicates that the genome
58
transcription takes place in the nucleoplasm, near host Pol II localization. Genome
59
replication and double-helical vRNP formation reportedly involves several intranuclear
60
host factors, such as minichromosome maintenance helicase complex, UAP56, Tat-SF1,
61
and ANP32
13
. Additionally, recent studies have demonstrated the importance of the
62
intranuclear proteins fragile X mental retardation protein (FMRP), protein kinase C, and
63
LYAR in the replication-coupled vRNP assembly
14-16
. However, since these host
64
proteins are localized in different intranuclear domains, subnuclear site of vRNA
65
preprint (which was not certified by peer review) is the author/funder. All rights reserved. No reuse allowed without permission.
The copyright holder for thisthis version posted February 24, 2021. ; https://doi.org/10.1101/2021.02.24.432647doi: bioRxiv preprint
Citations
More filters
Journal ArticleDOI
Manipulation of Cellular Processes via Nucleolus Hijaking in the Course of Viral Infection in Mammals.

[...]

Olga V. Iarovaia1, E. S. Ioudinkova1, Artem K. Velichko1, Sergey V. Razin1
Russian Academy of Sciences1
25 Jun 2021-Cells
TL;DR: In this paper, the authors discuss the functional impact of viral proteins and nucleic acid interaction with the nucleolus during infection, and discuss how the interaction of viral and nucleolar proteins interferes with canonical and non-canonical functions of the nucleus and results in a change in the physiology of the host cell.
Abstract: Due to their exceptional simplicity of organization, viruses rely on the resources, molecular mechanisms, macromolecular complexes, regulatory pathways, and functional compartments of the host cell for an effective infection process. The nucleolus plays an important role in the process of interaction between the virus and the infected cell. The interactions of viral proteins and nucleic acids with the nucleolus during the infection process are universal phenomena and have been described for almost all taxonomic groups. During infection, proteins of the nucleolus in association with viral components can be directly used for the processes of replication and transcription of viral nucleic acids and the assembly and transport of viral particles. In the course of a viral infection, the usurpation of the nucleolus functions occurs and the usurpation is accompanied by profound changes in ribosome biogenesis. Recent studies have demonstrated that the nucleolus is a multifunctional and dynamic compartment. In addition to the biogenesis of ribosomes, it is involved in regulating the cell cycle and apoptosis, responding to cellular stress, repairing DNA, and transcribing RNA polymerase II-dependent genes. A viral infection can be accompanied by targeted transport of viral proteins to the nucleolus, massive release of resident proteins of the nucleolus into the nucleoplasm and cytoplasm, the movement of non-nucleolar proteins into the nucleolar compartment, and the temporary localization of viral nucleic acids in the nucleolus. The interaction of viral and nucleolar proteins interferes with canonical and non-canonical functions of the nucleolus and results in a change in the physiology of the host cell: cell cycle arrest, intensification or arrest of ribosome biogenesis, induction or inhibition of apoptosis, and the modification of signaling cascades involved in the stress response. The nucleolus is, therefore, an important target during viral infection. In this review, we discuss the functional impact of viral proteins and nucleic acid interaction with the nucleolus during infection.
References
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Does the higher order structure of the influenza virus ribonucleoprotein guide sequence rearrangements in influenza viral RNA

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Philip A. Jennings1, John T. Finch1, Greg Winter1, James S. Robertson2
Laboratory of Molecular Biology1, University of Cambridge2
01 Sep 1983-Cell
TL;DR: The analysis of the sequence rearrangements found in sgRNAs indicates that they may be generated from the standard viral segments by a jumping viral polymerase that makes transitions between adjacent regions of the RNA template in the ribonucleoprotein tertiary structure.

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Host- and Strain-Specific Regulation of Influenza Virus Polymerase Activity by Interacting Cellular Proteins

[...]

Eric Bortz1, Liset Westera2, Jad Maamary1, John Steel1, John Steel3, Randy A. Albrecht1, Balaji Manicassamy1, Geoffrey Chase4, Luis Martinez-Sobrido5, Martin Schwemmle4, Adolfo García-Sastre1 
Icahn School of Medicine at Mount Sinai1, Utrecht University2, Emory University3, University of Freiburg4, University of Rochester5
01 Sep 2011-Mbio
TL;DR: The chicken DDX17 homologue was required for efficient avian H5N1 infection in chicken DF-1 fibroblasts, suggesting that this conserved virus-host interaction contributes to PB2-dependent host species specificity of influenza virus and ultimately to the outcome of human HPAI infections.
Abstract: Highly pathogenic avian influenza A (HPAI) viruses of the H5N1 subtype have recently emerged from avian zoonotic reservoirs to cause fatal human disease. Adaptation of HPAI virus RNA-dependent RNA polymerase (PB1, PB2, and PA proteins) and nucleoprotein (NP) to interactions with mammalian host proteins is thought to contribute to the efficiency of viral RNA synthesis and to disease severity. While proteomics experiments have identified a number of human proteins that associate with H1N1 polymerases and/or viral ribonucleoprotein (vRNP), how these host interactions might regulate influenza virus polymerase functions and host adaptation has been largely unexplored. We took a functional genomics (RNA interference [RNAi]) approach to assess the roles of a network of human proteins interacting with influenza virus polymerase proteins in viral polymerase activity from prototype H1N1 and H5N1 viruses. A majority (18 of 31) of the cellular proteins tested, including RNA-binding (DDX17, DDX5, NPM1, and hnRNPM), stress (PARP1, DDB1, and Ku70/86), and intracellular transport proteins, were required for efficient activity of both H1N1 and H5N1 polymerases. NXP2 and NF90 antagonized both polymerases, and six more RNA-associated proteins exhibited strain-specific phenotypes. Remarkably, 12 proteins differentially regulated H5N1 polymerase according to PB2 genotype at mammalian-adaptive residue 627. Among these, DEAD box RNA helicase DDX17/p72 facilitated efficient human-adapted (627K) H5N1 virus mRNA and viral RNA (vRNA) synthesis in human cells. Likewise, the chicken DDX17 homologue was required for efficient avian (627E) H5N1 infection in chicken DF-1 fibroblasts, suggesting that this conserved virus-host interaction contributes to PB2-dependent host species specificity of influenza virus and ultimately to the outcome of human HPAI infections. IMPORTANCE Highly pathogenic avian influenza A (HPAI) viruses have recently emerged from wild and domestic birds to cause fatal human disease. In human patients, it is thought that adaptation of the viral polymerase, a complex of viral proteins responsible for viral gene expression and RNA genome replication, to interactions with mammalian rather than avian host proteins contributes to disease severity. In this study, we used computational analysis and RNA interference (RNAi) experiments to identify a biological network of human proteins that regulates an H5N1 HPAI virus polymerase, in comparison to a mammalian H1N1 virus. Of 31 proteins tested, 18 (58%) were required for polymerase function in both HPAI and H1N1 viruses. Remarkably, we also found proteins such as DDX17 that governed the HPAI virus polymerase’s adaptation to human cells. These virus-host interactions may thus control pathogenicity of HPAI virus in humans and are promising therapeutic targets for antiviral drugs in severe influenza infections.

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RAB11A Is Essential for Transport of the Influenza Virus Genome to the Plasma Membrane

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Amie J. Eisfeld1, Eiryo Kawakami2, Tokiko Watanabe, Gabriele Neumann1, Yoshihiro Kawaoka 
University of Wisconsin-Madison1, University of Tokyo2
01 Jul 2011-Journal of Virology
TL;DR: The results uncover a critical host factor with an essential contribution to influenza virus genome delivery and reveal a potential role for RAB11A in the transport of ribonucleoprotein cargo.
Abstract: Influenza A virus assembly is a complex process that requires the intersection of pathways involved in transporting viral glycoproteins, the matrix protein, and viral genomes, incorporated in the viral ribonucleoprotein (vRNP) complex, to plasma membrane sites of virion formation. Among these virion components, the mechanism of vRNP delivery is the most incompletely understood. Here, we reveal a functional relationship between the cellular Rab11 GTPase isoform, RAB11A, and vRNPs and show that RAB11A is indispensable for proper vRNP transport to the plasma membrane. Using an immunofluorescence-based assay with a monoclonal antibody that recognizes nucleoprotein in the form of vRNP, we demonstrate association between RAB11A and vRNPs at all stages of vRNP cytoplasmic transport. Abrogation of RAB11A expression through small interfering RNA (siRNA) treatment or disruption of RAB11A function by overexpression of dominant negative or constitutively active proteins caused aberrant vRNP intracellular accumulation, retention in the perinuclear region, and lack of accumulation at the plasma membrane. Complex formation between RAB11A and vRNPs was further established biochemically. Our results uncover a critical host factor with an essential contribution to influenza virus genome delivery and reveal a potential role for RAB11A in the transport of ribonucleoprotein cargo.

158 citations

Journal ArticleDOI
Translocation of nucleolar phosphoprotein B23 (37kDapI 5.1) induced by selective inhibitors of ribosome synthesis

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Benjamin Yat-Ming Yung1, Harris Busch1, Pui-Kwong Chan1
Baylor College of Medicine1
18 Dec 1985-Biochimica et Biophysica Acta
TL;DR: To elucidate the possible role of nucleolar phosphoprotein B23 in ribosome synthesis, drugs which inhibit the processing of ribosomal RNA were employed and protein B23 was found co-localized with the pre-rRNPs as determined by ELISA assays which agrees with previous studies.

153 citations

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Trending Questions (1)
What nucleates the formation of the nucleolus?

The nucleolus is nucleated by the localization of viral nucleoprotein, a key component of the influenza virus ribonucleoprotein complex, crucial for functional vRNP formation in the nucleolus.

See answers from 5 other papers