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Structural Insight into RNA Synthesis by Influenza D Polymerase

Overview
Journal Nat Microbiol
Specialties Microbiology
Parasitology
Date 2019 Jun 19
PMID 31209309
Citations 42
Authors
Qi Peng
Yuqian Liu
Ruchao Peng
Min Wang
Wei Yang
Hao Song
Yuhai Chen
Sheng Liu
Min Han
Xinzheng Zhang
Peiyi Wang
Jinghua Yan
Buchang Zhang
Jianxun Qi
Tao Deng
George F Gao
Yi Shi
Affiliations
Soon will be listed here.
Abstract

The influenza virus polymerase uses capped RNA primers to initiate transcription, and a combination of terminal and internal de novo initiations for the two-step replication process by binding the conserved viral genomic RNA (vRNA) or complementary RNA (cRNA) promoter. Here, we determined the apo and promoter-bound influenza D polymerase structures using cryo-electron microscopy and found the polymerase has an evolutionarily conserved stable core structure with inherently flexible peripheral domains. Strikingly, two conformations (mode A and B) of the vRNA promoter were observed where the 3'-vRNA end can bind at two different sites, whereas the cRNA promoter only binds in the mode B conformation. Functional studies confirmed the critical role of the mode B conformation for vRNA synthesis via the intermediate cRNA but not for cRNA production, which is mainly regulated by the mode A conformation. Both conformations participate in the regulation of the transcription process. This work advances our understanding of the regulatory mechanisms for the synthesis of different RNA species by influenza virus polymerase and opens new opportunities for antiviral drug design.

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References
1.
Muraki Y, Hongo S . The molecular virology and reverse genetics of influenza C virus. Jpn J Infect Dis. 2010; 63(3):157-65. View
2.
Hatakeyama S, Kawaoka Y . [The molecular basis of resistance to anti-influenza drugs]. Nihon Rinsho. 2006; 64(10):1845-52. View
3.
Mikulasova A, Vareckova E, Fodor E . Transcription and replication of the influenza a virus genome. Acta Virol. 2001; 44(5):273-82. View
4.
Reich S, Guilligay D, Cusack S . An in vitro fluorescence based study of initiation of RNA synthesis by influenza B polymerase. Nucleic Acids Res. 2017; 45(6):3353-3368. PMC: 5399792. DOI: 10.1093/nar/gkx043. View