Defining Basic Rules for Hardening Influenza A Virus Liquid Condensates

Overview

Journal Elife

Specialty Biology

Date 2023 Apr 4

PMID 37013374

Authors

Temitope Akhigbe Etibor

Silvia Vale-Costa

Sindhuja Sridharan

Daniela Bras

Isabelle Becher

Victor Hugo Mello

Filipe Ferreira

Marta Alenquer

Mikhail M Savitski

Maria-Joao Amorim

Affiliations

Soon will be listed here.

Abstract

In biological systems, liquid and solid-like biomolecular condensates may contain the same molecules but their behaviour, including movement, elasticity, and viscosity, is different on account of distinct physicochemical properties. As such, it is known that phase transitions affect the function of biological condensates and that material properties can be tuned by several factors including temperature, concentration, and valency. It is, however, unclear if some factors are more efficient than others at regulating their behaviour. Viral infections are good systems to address this question as they form condensates as part of their replication programmes. Here, we used influenza A virus (IAV) liquid cytosolic condensates, AKA viral inclusions, to provide a proof of concept that liquid condensate hardening via changes in the valency of its components is more efficient than altering their concentration or the temperature of the cell. Liquid IAV inclusions may be hardened by targeting vRNP (viral ribonucleoprotein) interactions via the known NP (nucleoprotein) oligomerising molecule, nucleozin, both and without affecting host proteome abundance nor solubility. This study is a starting point for understanding how to pharmacologically modulate the material properties of IAV inclusions and may offer opportunities for alternative antiviral strategies.

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