1. Nucleoside Analogs and Perylene Derivatives Modulate Phase Separation of SARS-CoV-2 N Protein and Genomic RNA In Vitro
- Author
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Julia Svetlova, Ekaterina Knizhnik, Valentin Manuvera, Vyacheslav Severov, Dmitriy Shirokov, Ekaterina Grafskaia, Pavel Bobrovsky, Elena Matyugina, Anastasia Khandazhinskaya, Liubov Kozlovskaya, Nataliya Miropolskaya, Andrey Aralov, Yuri Khodarovich, Vladimir Tsvetkov, Sergey Kochetkov, Vassili Lazarev, and Anna Varizhuk
- Subjects
SARS-CoV-2 ,Organic Chemistry ,COVID-19 ,Nucleosides ,General Medicine ,Antiviral Agents ,Catalysis ,Computer Science Applications ,Inorganic Chemistry ,phase separation ,nucleocapsid protein ,RNA ,small-molecule antivirals ,Humans ,Physical and Theoretical Chemistry ,Perylene ,Molecular Biology ,Spectroscopy - Abstract
The life cycle of severe acute respiratory syndrome coronavirus 2 includes several steps that are supposedly mediated by liquid–liquid phase separation (LLPS) of the viral nucleocapsid protein (N) and genomic RNA. To facilitate the rational design of LLPS-targeting therapeutics, we modeled N-RNA biomolecular condensates in vitro and analyzed their sensitivity to several small-molecule antivirals. The model condensates were obtained and visualized under physiological conditions using an optimized RNA sequence enriched with N-binding motifs. The antivirals were selected based on their presumed ability to compete with RNA for specific N sites or interfere with non-specific pi–pi/cation–pi interactions. The set of antivirals included fleximers, 5′-norcarbocyclic nucleoside analogs, and perylene-harboring nucleoside analogs as well as non-nucleoside amphiphilic and hydrophobic perylene derivatives. Most of these antivirals enhanced the formation of N-RNA condensates. Hydrophobic perylene derivatives and 5′-norcarbocyclic derivatives caused up to 50-fold and 15-fold enhancement, respectively. Molecular modeling data argue that hydrophobic compounds do not hamper specific N-RNA interactions and may promote non-specific ones. These findings shed light on the determinants of potent small-molecule modulators of viral LLPS.
- Published
- 2022
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