A Structure-Based Model for the Complete Transcription Cycle of Influenza Polymerase

Wandzik, J.M.; Kouba, T.; Krishnan, M.; Pflug, A.; Drncová, Petra; Provazník, Jan; Azevedo, Nayara; Cusack, Stephen

doi:10.1016/j.cell.2020.03.061

Cited by 105 publications

(260 citation statements)

References 51 publications

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“…B-C. Phospho-sites on PB1 surround the catalytic core and template entry. The location of PB1 phospho-sites characterized in this study are modeled in yellow on (B) a pre-initiation complex (PDB 4WSB [ 44 ]) or (C) a transcriptional elongation complex (PDB 6T0V [ 36 ]). The motif C residues D445/D446 in the catalytic site are in orange, 5’ vRNA is light blue, 3’ vRNA is magenta, and transcription product is dark blue.…”

Section: Resultsmentioning

confidence: 99%

“…The potential impact of phosphorylation at each site was proposed based on polymerase structures ( S1 Table ). In addition to evaluating conservation of identified phosphorylated residues, we calculated the surface accessibility of each residue in multiple polymerase states: the monomeric polymerase bound to either vRNA [ 34 ] or cRNA [ 21 ], dimerized polymerase bound to cRNA [ 35 ], and polymerase during transcription elongation[ 36 ] ( S2 Table ). Residues corresponding to WSN PB1 T223, T385, S478 and T570 were inaccessible in all conformations analyzed, PB1 S384 was accessible in all conformations, and S673 was buried in the vRNA-bound structure but may be accessible in the monomeric.…”

Section: Resultsmentioning

confidence: 99%

“…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 ]. Two of our PB1 phospho-mutants may affect this process.…”

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: Resultsmentioning

confidence: 99%

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Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

et al. 2020

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“…It is also of primary importance to carefully select the acquisition parameters (pixel size and defocus range) according to the expected/desired resolution in order to get the maximum out of the data-collection session. We now routinely collect SPA data sets using active beam-tilt compensation and fringe-free imaging at a pixel size of $0.8 Å (Wandzik et al, 2020;Qi, Di Minin et al, 2019;Qi, Sorrentino et al, 2019;Cannac et al, 2020;Flaugnatti et al, 2020;Zivanov et al, 2018;Muir et al, 2020;Oosterheert et al, 2018) or even smaller (Weis et al, 2019). The ability to collect more/better data in a shorter time allows increasingly dynamic, flexible and heterogeneous complexes to be imaged (time-resolved studies, mechanistic studies etc.…”

Section: Resultsmentioning

confidence: 99%

Combining high throughput and high quality for cryo-electron microscopy data collection

Weis

Hagen

2020

Acta Crystallogr D Struct Biol

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Cryo-electron microscopy (cryo-EM) can be used to elucidate the 3D structure of macromolecular complexes. Driven by technological breakthroughs in electron-microscope and electron-detector development, coupled with improved image-processing procedures, it is now possible to reach high resolution both in single-particle analysis and in cryo-electron tomography and subtomogram-averaging approaches. As a consequence, the way in which cryo-EM data are collected has changed and new challenges have arisen in terms of microscope alignment, aberration correction and imaging parameters. This review describes how high-end data collection is performed at the EMBL Heidelberg cryo-EM platform, presenting recent microscope implementations that allow an increase in throughput while maintaining aberration-free imaging and the optimization of acquisition parameters to collect high-resolution data.

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“…Cryo-electron microscopy (cryo-EM) has become a mainstream technique for determining the structures of macromolecular complexes at close-to-atomic resolution and ultimately for building an atomic model (Ge, Scholl et al 2020, Wandzik, Kouba et al 2020. With its unique ability to reconstruct multiple conformations and compositions of the macromolecular complexes, cryo-EM allows the understanding of the structural and assembly dynamics of macromolecular complexes in their native conditions (Davis, Tan et al 2016, Plaschka, Lin et al 2017, Razi, Davis et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Local computational methods to improve the interpretability and analysis of cryo-EM maps

Kaur

Gómez-Blanco

Khalifa

et al. 2020

Preprint

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Cryo-electron microscopy (cryo-EM) maps usually show heterogeneous distributions of B-factors and electron density occupancies and are typically B-factor sharpened to improve their contrast and interpretability at high-resolutions. However, 'over-sharpening' due to the application of a single global B-factor can distort processed maps causing connected densities to appear broken and disconnected. This issue limits the interpretability of cryo-EM maps, i.e. ab initio modelling.In this work, we propose 1) approaches to enhance high-resolution features of cryo-EM maps, while preventing map distortions and 2) methods to obtain local B-factors and electron density occupancy maps. These algorithms have as common link the use of the spiral phase transformation and are called LocSpiral, LocBSharpen, LocBFactor and LocOccupancy. Our results, which

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A Structure-Based Model for the Complete Transcription Cycle of Influenza Polymerase

Cited by 105 publications

References 51 publications

Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

Phosphorylation controls RNA binding and transcription by the influenza virus polymerase

Combining high throughput and high quality for cryo-electron microscopy data collection

Local computational methods to improve the interpretability and analysis of cryo-EM maps

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