Author: Villagomez-Bernabe, B.; Chan, S. W.; Coulter, J. A.; Roseman, A. M.; Currell, F. J.
Title: Fast Ion Beam Inactivation of Viruses, Where Radiation Track Structure Meets RNA Structural Biology Cord-id: nbgyba5b Document date: 2020_9_21
ID: nbgyba5b
Snippet: Here we show an interplay between the structures present in ionization tracks and nucleocapsid RNA structural biology, using fast ion beam inactivation of the severe acute respiratory syndrome coronavirus (SARS-CoV) virion as an example. This interplay is one of the key factors in predicting dose-inactivation curves for high energy ion beam inactivation of virions. We also investigate the adaptation of well-established cross-section data derived from radiation interactions with water to the inte
Document: Here we show an interplay between the structures present in ionization tracks and nucleocapsid RNA structural biology, using fast ion beam inactivation of the severe acute respiratory syndrome coronavirus (SARS-CoV) virion as an example. This interplay is one of the key factors in predicting dose-inactivation curves for high energy ion beam inactivation of virions. We also investigate the adaptation of well-established cross-section data derived from radiation interactions with water to the interactions involving the components of a virion, going beyond the density-scaling approximation developed previously. We conclude that solving one of the grand challenges of structural biology — the determination of RNA tertiary/quaternary structure — is intimately linked to predicting ion-beam inactivation of viruses and that the two problems can be mutually informative. Indeed, our simulations show that fast ion beams have a key role to play in elucidating RNA tertiary/quaternary structure.
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