4.5 Article

Role of spatial patterning of N-protein interactions in SARS-CoV-2 genome packaging

期刊

BIOPHYSICAL JOURNAL
卷 120, 期 14, 页码 2771-2784

出版社

CELL PRESS
DOI: 10.1016/j.bpj.2021.06.018

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资金

  1. National Science Foundation [ACI-1548562]
  2. National Institutes of Health [R01 GM081506, T32 CA 9156-43, F32GM136164]
  3. L'OREAL USA for Women in Science Fellowship
  4. Air Force Office of Scientific Research [FA9550-20-1-0241]
  5. FastGrant

向作者/读者索取更多资源

Viruses efficiently package their genomes through specific packaging signals and liquid-liquid phase separation (LLPS) of viral proteins. The positioning and abundance of LLPS-promoting elements play a critical role in genome compaction and cyclization.
Viruses must efficiently and specifically package their genomes while excluding cellular nucleic acids and viral subgenomic fragments. Some viruses use specific packaging signals, which are conserved sequence or structure motifs present only in the full-length genome. Recent work has shown that viral proteins important for packaging can undergo liquid-liquid phase separation (LLPS), in which one or two viral nucleic acid binding proteins condense with the genome. The compositional simplicity of viral components lends itself well to theoretical modeling compared with more complex cellular organelles. Viral LLPS can be limited to one or two viral proteins and a single genome that is enriched in LLPS-promoting features. In our previous study, we observed that LLPS-promoting sequences of severe acute respiratory syndrome coronavirus 2 are located at the 50 and 30 ends of the genome, whereas the middle of the genome is predicted to consist mostly of solubilizing elements. Is this arrangement sufficient to drive single genome packaging, genome compaction, and genome cyclization? We addressed these questions using a coarse-grained polymer model, LASSI, to study the LLPS of nucleocapsid protein with RNA sequences that either promote LLPS or solubilization. With respect to genome cyclization, we find the most optimal arrangement restricts LLPS-promoting elements to the 50 and 30 ends of the genome, consistent with the native spatial patterning. Genome compaction is enhanced by clustered LLPS-promoting binding sites, whereas single genome packaging is most efficient when binding sites are distributed throughout the genome. These results suggest that many and variably positioned LLPS-promoting signals can support packaging in the absence of a singular packaging signal which argues against necessity of such a feature. We hypothesize that this model should be generalizable to multiple viruses as well as cellular organelles such as paraspeckles, which enrich specific long RNA sequences in a defined arrangement.

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