Structure and Function of the Influenza Virus Transcription and Replication Machinery

Fodor, Ervin; Velthuis, Aartjan J.W. te

doi:10.1101/cshperspect.a038398

Cited by 102 publications

(100 citation statements)

References 85 publications

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“…Polymerase activity requires multiple steps for successful replication and transcription, beginning with protein expression, trimer assembly, RNA binding, RNP assembly, and ultimately the synthesis of new RNA products [ 39 ]. Primer extension reports on the cumulative success of this process.…”

Section: Resultsmentioning

confidence: 99%

“…The influenza polymerase performs diverse functions as transcription peaks early in infection, followed by production of the replication intermediate cRNA, and ultimately the final replication product vRNA [ 23 ]. The different functions are achieved in part by discrete conformations of the viral polymerase [ 39 , 41 ]. All of these require appropriate binding and positioning of the template [ 21 , 34 , 36 , 42 ].…”

Section: Discussionmentioning

confidence: 99%

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Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

et al. 2020

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The influenza virus polymerase transcribes and replicates the viral genome. The proper timing and balance of polymerase activity is important for successful replication. Genome replication is controlled in part by phosphorylation of NP that regulates assembly of the replication machinery. However, it remains unclear whether phosphorylation directly regulated polymerase activity. Here we identified polymerase phosphosites that control its function. Mutating phosphosites in the catalytic subunit PB1 altered polymerase activity and virus replication. Biochemical analyses revealed phosphorylation events that disrupted global polymerase function by blocking the NTP entry channel or preventing RNA binding. We also identified a regulatory site that split polymerase function by specifically suppressing transcription. These experiments show that host kinases phospho-regulate viral RNA synthesis directly by modulating polymerase activity and indirectly by controlling assembly of replication machinery. Further, they suggest polymerase phosphorylation may bias replication versus transcription at discrete times or locations during the infectious cycle.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

et al. 2020

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“…33 It has been suggested that ANP32A plays a role in assembly or regulation of this dimerization process, for example, by recruitment of a second polymerase to apo polymerase for the formation of viral RNPs. 37 In this context the polyvalent nature of the interaction between ANP32A and 627-NLS may be of functional relevance. In particular, the more extensive effective capture radius of the IDD of avANP32A may be important.…”

Section: Discussionmentioning

confidence: 99%

Molecular Basis of Host-Adaptation Interactions between Influenza Virus Polymerase PB2 Subunit and ANP32A

Zarco

Kalayil

Maurin

et al. 2020

Preprint

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Avian influenza polymerase undergoes host adaptation in order to efficiently replicate in human cells.Adaptive mutants are localised on the C-terminal (627-NLS) domains of the PB2 subunit. In particular mutation of PB2 residue 627 from E to K in avian polymerase rescues activity in mammalian cells. A host transcription regulator ANP32A, comprising a long C-terminal intrinsically disordered domain (IDD), has also been shown to be responsible for this viral adaptation. Human ANP32A IDD lacks a 33 residue insertion compared to avian ANP32A, a deletion that restricts avian influenza polymerase activity in mammalian cells. We determined conformational descriptions of the highly dynamic complexes between 627E and 627K forms of the 627-NLS domains of PB2 and avian and human ANP32A. The negatively charged intrinsically disordered domain of human ANP32A transiently binds to a basic face of the 627 domain, exploiting multiple binding sites to maximize affinity for 627-NLS.This interaction also implicates residues 590 and 591 that are responsible for human-adaptation of the the 2009 pandemic influenza polymerase. The presence of 627E interrupts the polyvalency of the interaction, an effect that is compensated by extending the interaction surface and exploiting an avianunique motif in the unfolded domain that interacts with the 627-NLS linker. In both cases the interaction favours the open, dislocated form of the 627-NLS domains. Importantly the two binding modes exploited by human-and avian-adapted PB2 are strongly abrogated in the cross interaction between avian polymerase and human ANP32A, suggesting that this molecular specificity may be related to species adaptation. The observed binding mode is maintained in the context of heterotrimeric influenza polymerase, placing ANP32A in the immediate vicinity of known host-adaptive PB2 mutants. This study provides a molecular framework for understanding the species-specific restriction of influenza polymerase by ANP32A and will inform the identification of new targets for influenza inhibition.

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“…Cap snatching is carried out by the RdRp utilizing the PB2 cap-binding domain (residues 320-485) and the PA endonuclease (residues 1-196). The 10-to 15-nt capped host RNA fragments are then used as primers for transcription of viral mRNA (for review, see Fodor and te Velthuis 2019;Wandzik et al 2020).…”

Section: Transcriptionmentioning

confidence: 99%

“…Additional adaptations are believed to counteract mammalian antiviral immune pathways. The retinoic acidinducible gene 1 protein (RIG-I) recognizes influenza vRNA on the basis of a 5 0 -terminal triphosphate moiety and an adjacent patch of double-stranded RNA (dsRNA) that is the viral promoter binding the RdRp (for review, see Fodor and te Velthuis 2019;Wandzik et al 2020). During infection, the viral NS1 protein counteracts RIG-I, which would otherwise result in the induction of interferon (IFN) and IFN-stimulated gene (ISG) expression, such as MX1, protein kinase R (PKR), and IFITM3 (Pichlmair et al 2006;Rehwinkel et al 2010;Rajsbaum et al 2012).…”

mentioning

confidence: 99%

Host Cell Factors That Interact with Influenza Virus Ribonucleoproteins

Staller

Barclay

2020

Cold Spring Harb Perspect Med

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Influenza viruses hijack host cell factors at each stage of the viral life cycle. After host cell entry and endosomal escape, the influenza viral ribonucleoproteins (vRNPs) are released into the cytoplasm where the classical cellular nuclear import pathway is usurped for nuclear translocation of the vRNPs. Transcription takes place inside the nucleus at active host transcription sites, and cellular mRNA export pathways are subverted for export of viral mRNAs. Newly synthesized RNP components cycle back into the nucleus using various cellular nuclear import pathways and host-encoded chaperones. Replication of the negative-sense viral RNA (vRNA) into complementary RNA (cRNA) and back into vRNA requires complex interplay between viral and host factors. Progeny vRNPs assemble at the host chromatin and subsequently exit from the nucleus-processes orchestrated by sets of host and viral proteins. Finally, several host pathways appear to play a role in vRNP trafficking from the nuclear envelope to the plasma membrane for egress.

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Structure and Function of the Influenza Virus Transcription and Replication Machinery

Cited by 102 publications

References 85 publications

Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

Molecular Basis of Host-Adaptation Interactions between Influenza Virus Polymerase PB2 Subunit and ANP32A

Host Cell Factors That Interact with Influenza Virus Ribonucleoproteins

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