Enhanced inter-chain hydrogen bonding in the murine norovirus VP1 capsid leads to increased particle stability and delayed viral uncoating

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Abstract

Capsid stability is vital for virion survival as the capsid must withstand varying environmental challenges such as pH and temperature to allow the virus to reach a target cell. Noroviruses are non-enveloped, icosahedral, positive-sense RNA viruses of importance to human health globally, with no approved vaccine or antiviral available. Despite this, the molecular mechanisms behind norovirus capsid stability and capsid rearrangement prior to RNA translocation are understudied. Using murine norovirus as a model, we utilised thermal stress to create a thermally stable virus population. By introducing three identified substitutions in the major capsid protein VP1 from this virus population into an infectious clone, we were able to create a heat and pH stable virus that had delayed viral uncoating during the infectious lifecycle. Cryo-EM reconstructions of the triple substitution virus demonstrated that enhanced inter-chain hydrogen bonding was vital for increased capsid stability. Finally, mutagenesis to remove the enhanced inter-chain hydrogen bonding reverted capsid stability back to wild-type levels. This work contributes to fundamental calicivirus biology by demonstrating areas of importance in capsid stability down to amino acid resolution. Furthermore, this work could inform vaccine design for a thermostable norovirus vaccine in the future.

Author Summary

Noroviruses cause gastroenteritis and globally contribute to the death of up to 250,000 people worldwide per annum and an estimated healthcare cost of $4 billion. Despite this, there is no vaccine or antiviral treatment available, thus more work needs to be conducted to understand the mechanisms that underpin the viral life cycle. The norovirus capsid is a meta-stable shell-like structure evolved to protect the viral RNA from the harsh external environment, until cellular triggers allow genome release to initiate infection of a host cell. However, the molecular interactions that are key for controlling this balance are relatively unstudied. In this report, we identify that hydrogen bonding at the capsid protomer-protomer interface are vital for maintaining this balance, with increased inter-molecular hydrogen bonding at three specific amino acids able to increase viral stability whilst still permitting infectious genome release. Furthermore, reducing inter-molecular hydrogen bonding at these crucial amino acids was able to reverse this mechanism. These results should inform future norovirus vaccine studies, where thermostable virus-like-particles are needed to overcome issues with cold-chain storage.

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