Enhanced RNA replication and pathogenesis in recent SARS-CoV-2 variants harboring the L260F mutation in NSP6

  1. Taha Y. Taha
  2. Shahrzad Ezzatpour
  3. Jennifer M. Hayashi
  4. Chengjin Ye
  5. Francisco J. Zapatero-Belinchón
  6. Julia A. Rosecrans
  7. Gabriella R. Kimmerly
  8. Irene P. Chen
  9. Keith Walcott
  10. Anna Kurianowicz
  11. Danielle M. Jorgens
  12. Natalie R. Chaplin
  13. Annette Choi
  14. David W. Buchholz
  15. Julie Sahler
  16. Zachary T Hilt
  17. Brian Imbiakha
  18. Cecilia Vagi-Szmola
  19. Mauricio Montano
  20. Erica Stevenson
  21. Martin Gordon
  22. Danielle L. Swaney
  23. Nevan J. Krogan
  24. Luis Martinez-Sobrido
  25. Hector C. Aguilar
  26. Melanie Ott
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Abstract

The COVID-19 pandemic has been driven by SARS-CoV-2 variants with enhanced transmission and immune escape. Apart from extensive evolution in the Spike protein, non-Spike mutations are accumulating across the entire viral genome and their functional impact is not well understood. To address the contribution of these mutations, we reconstructed genomes of recent Omicron variants with disabled Spike expression (replicons) to systematically compare their RNA replication capabilities independently from Spike. We also used a single reference replicon and complemented it with various Omicron variant Spike proteins to quantify viral entry capabilities in single-round infection assays. Viral entry and RNA replication were negatively correlated, suggesting that as variants evolve reduced entry functions under growing immune pressure on Spike, RNA replication increases as a compensatory mechanism. We identified multiple mutations across the viral genome that enhanced viral RNA replication. NSP6 emerged as a hotspot with a distinct L260F mutation independently arising in the BQ.1.1 and XBB.1.16 variants. Using mutant and revertant NSP6 viral clones, the L260F mutation was validated to enhance viral replication in cells and increase pathogenesis in mice. Notably, this mutation enhanced host lipid droplet consumption by NSP6 without impacting its known ER-zippering function or double-membrane vesicle morphology. Collectively, a systematic analysis of RNA replication of recent Omicron variants defined NSP6’s key role in viral RNA replication that provides insight into evolutionary trajectories of recent variants with possible therapeutic implications.

Author Summary

As SARS-CoV-2 continues to spread and adapt in humans, viral variants with enhanced spread and immune evasion have emerged throughout the COVID-19 pandemic. While most of the mutations occur in the Spike protein and have been extensively studied, non-Spike mutations have been accumulating and are not as well understood. Here, we constructed Spike-defective genomes of recent Omicron variants and systematically compared their RNA replication capabilities independently from Spike. We also performed single-round infection assays with various Omicron variant Spike proteins to quantify viral entry capabilities. Interestingly, viral entry and RNA replication were negatively correlated, suggesting that as variants evolved reduced entry functions under growing immune pressure on Spike, RNA replication increased as a compensatory mechanism. We focused on a viral protein NSP6 that acquired mutations that significantly enhanced RNA replication. We validated that a frequently accessed L260F mutation in NSP6 enhanced viral infection in cells and increased pathogenesis in mice. While the mutation did not alter NSP6’s role in maintaining a membranous network of viral replication factories, the mutation enhanced viral hijacking of the host lipid droplet machinery. Collectively, we highlight the important role of non-Spike mutations in the evolutionary trajectories of SARS-CoV-2 variants with possible monitoring and therapeutic implications.

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  1. Version published to 10.1101/2024.12.30.628795v1 on bioRxiv