Deconstructing virus condensation

Viruses have evolved precise mechanisms for using the cellular physiological pathways for their perpetuation. These virus-driven biochemical events must be separated in space and time from those of the host cell. In recent years, granular structures, known for over a century for rabies virus, were s...

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Veröffentlicht in:	PLoS pathogens 2021-10, Vol.17 (10), p.e1009926-e1009926
Hauptverfasser:	Lopez, Nora, Camporeale, Gabriela, Salgueiro, Mariano, Borkosky, Silvia Susana, Visentín, Araceli, Peralta-Martinez, Ramon, Loureiro, María Eugenia, de Prat-Gay, Gonzalo
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Sprache:	eng
Schlagworte:	Biochemistry Biology and Life Sciences Condensates Condensation Critical point Cytoplasm Dengue fever Enzymes Genomes Hepatitis Host-virus relationships Inclusion bodies Infections Irritable bowel syndrome Lipids Liquid phases Lyssavirus Nucleoproteins Organelles Phase separation Physical Sciences Polymer solubility Positive feedback Principles Proteins Rabies Replication Review Ribonucleic acid RNA RNA polymerase RNA viruses Severe acute respiratory syndrome coronavirus 2 Solvents Structure Transcription Viral proteins Virus research Viruses West Nile virus Zika virus
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creator	Lopez, Nora Camporeale, Gabriela Salgueiro, Mariano Borkosky, Silvia Susana Visentín, Araceli Peralta-Martinez, Ramon Loureiro, María Eugenia de Prat-Gay, Gonzalo
description	Viruses have evolved precise mechanisms for using the cellular physiological pathways for their perpetuation. These virus-driven biochemical events must be separated in space and time from those of the host cell. In recent years, granular structures, known for over a century for rabies virus, were shown to host viral gene function and were named using terms such as viroplasms, replication sites, inclusion bodies, or viral factories (VFs). More recently, these VFs were shown to be liquid-like, sharing properties with membrane-less organelles driven by liquid–liquid phase separation (LLPS) in a process widely referred to as biomolecular condensation. Some of the best described examples of these structures come from negative stranded RNA viruses, where micrometer size VFs are formed toward the end of the infectious cycle. We here discuss some basic principles of LLPS in connection with several examples of VFs and propose a view, which integrates viral replication mechanisms with the biochemistry underlying liquid-like organelles. In this view, viral protein and RNA components gradually accumulate up to a critical point during infection where phase separation is triggered. This yields an increase in transcription that leads in turn to increased translation and a consequent growth of initially formed condensates. According to chemical principles behind phase separation, an increase in the concentration of components increases the size of the condensate. A positive feedback cycle would thus generate in which crucial components, in particular nucleoproteins and viral polymerases, reach their highest levels required for genome replication. Progress in understanding viral biomolecular condensation leads to exploration of novel therapeutics. Furthermore, it provides insights into the fundamentals of phase separation in the regulation of cellular gene function given that virus replication and transcription, in particular those requiring host polymerases, are governed by the same biochemical principles.
doi_str_mv	10.1371/journal.ppat.1009926
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These virus-driven biochemical events must be separated in space and time from those of the host cell. In recent years, granular structures, known for over a century for rabies virus, were shown to host viral gene function and were named using terms such as viroplasms, replication sites, inclusion bodies, or viral factories (VFs). More recently, these VFs were shown to be liquid-like, sharing properties with membrane-less organelles driven by liquid–liquid phase separation (LLPS) in a process widely referred to as biomolecular condensation. Some of the best described examples of these structures come from negative stranded RNA viruses, where micrometer size VFs are formed toward the end of the infectious cycle. We here discuss some basic principles of LLPS in connection with several examples of VFs and propose a view, which integrates viral replication mechanisms with the biochemistry underlying liquid-like organelles. In this view, viral protein and RNA components gradually accumulate up to a critical point during infection where phase separation is triggered. This yields an increase in transcription that leads in turn to increased translation and a consequent growth of initially formed condensates. According to chemical principles behind phase separation, an increase in the concentration of components increases the size of the condensate. A positive feedback cycle would thus generate in which crucial components, in particular nucleoproteins and viral polymerases, reach their highest levels required for genome replication. Progress in understanding viral biomolecular condensation leads to exploration of novel therapeutics. Furthermore, it provides insights into the fundamentals of phase separation in the regulation of cellular gene function given that virus replication and transcription, in particular those requiring host polymerases, are governed by the same biochemical principles.</description><identifier>ISSN: 1553-7374</identifier><identifier>ISSN: 1553-7366</identifier><identifier>EISSN: 1553-7374</identifier><identifier>DOI: 10.1371/journal.ppat.1009926</identifier><identifier>PMID: 34648608</identifier><language>eng</language><publisher>San Francisco: Public Library of Science</publisher><subject>Biochemistry ; Biology and Life Sciences ; Condensates ; Condensation ; Critical point ; Cytoplasm ; Dengue fever ; Enzymes ; Genomes ; Hepatitis ; Host-virus relationships ; Inclusion bodies ; Infections ; Irritable bowel syndrome ; Lipids ; Liquid phases ; Lyssavirus ; Nucleoproteins ; Organelles ; Phase separation ; Physical Sciences ; Polymer solubility ; Positive feedback ; Principles ; Proteins ; Rabies ; Replication ; Review ; Ribonucleic acid ; RNA ; RNA polymerase ; RNA viruses ; Severe acute respiratory syndrome coronavirus 2 ; Solvents ; Structure ; Transcription ; Viral proteins ; Virus research ; Viruses ; West Nile virus ; Zika virus</subject><ispartof>PLoS pathogens, 2021-10, Vol.17 (10), p.e1009926-e1009926</ispartof><rights>COPYRIGHT 2021 Public Library of Science</rights><rights>2021 Lopez et al. 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These virus-driven biochemical events must be separated in space and time from those of the host cell. In recent years, granular structures, known for over a century for rabies virus, were shown to host viral gene function and were named using terms such as viroplasms, replication sites, inclusion bodies, or viral factories (VFs). More recently, these VFs were shown to be liquid-like, sharing properties with membrane-less organelles driven by liquid–liquid phase separation (LLPS) in a process widely referred to as biomolecular condensation. Some of the best described examples of these structures come from negative stranded RNA viruses, where micrometer size VFs are formed toward the end of the infectious cycle. We here discuss some basic principles of LLPS in connection with several examples of VFs and propose a view, which integrates viral replication mechanisms with the biochemistry underlying liquid-like organelles. In this view, viral protein and RNA components gradually accumulate up to a critical point during infection where phase separation is triggered. This yields an increase in transcription that leads in turn to increased translation and a consequent growth of initially formed condensates. According to chemical principles behind phase separation, an increase in the concentration of components increases the size of the condensate. A positive feedback cycle would thus generate in which crucial components, in particular nucleoproteins and viral polymerases, reach their highest levels required for genome replication. Progress in understanding viral biomolecular condensation leads to exploration of novel therapeutics. Furthermore, it provides insights into the fundamentals of phase separation in the regulation of cellular gene function given that virus replication and transcription, in particular those requiring host polymerases, are governed by the same biochemical principles.</description><subject>Biochemistry</subject><subject>Biology and Life Sciences</subject><subject>Condensates</subject><subject>Condensation</subject><subject>Critical point</subject><subject>Cytoplasm</subject><subject>Dengue fever</subject><subject>Enzymes</subject><subject>Genomes</subject><subject>Hepatitis</subject><subject>Host-virus relationships</subject><subject>Inclusion bodies</subject><subject>Infections</subject><subject>Irritable bowel syndrome</subject><subject>Lipids</subject><subject>Liquid phases</subject><subject>Lyssavirus</subject><subject>Nucleoproteins</subject><subject>Organelles</subject><subject>Phase separation</subject><subject>Physical Sciences</subject><subject>Polymer solubility</subject><subject>Positive feedback</subject><subject>Principles</subject><subject>Proteins</subject><subject>Rabies</subject><subject>Replication</subject><subject>Review</subject><subject>Ribonucleic acid</subject><subject>RNA</subject><subject>RNA polymerase</subject><subject>RNA viruses</subject><subject>Severe acute respiratory syndrome coronavirus 2</subject><subject>Solvents</subject><subject>Structure</subject><subject>Transcription</subject><subject>Viral proteins</subject><subject>Virus research</subject><subject>Viruses</subject><subject>West Nile virus</subject><subject>Zika 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virus condensation</title><author>Lopez, Nora ; Camporeale, Gabriela ; Salgueiro, Mariano ; Borkosky, Silvia Susana ; Visentín, Araceli ; Peralta-Martinez, Ramon ; Loureiro, María Eugenia ; de Prat-Gay, Gonzalo</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c638t-69e7e025b7327bbbe1cf074e6e4ee5a493cee96b8673226b4460c385be09677f3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2021</creationdate><topic>Biochemistry</topic><topic>Biology and Life Sciences</topic><topic>Condensates</topic><topic>Condensation</topic><topic>Critical point</topic><topic>Cytoplasm</topic><topic>Dengue fever</topic><topic>Enzymes</topic><topic>Genomes</topic><topic>Hepatitis</topic><topic>Host-virus relationships</topic><topic>Inclusion bodies</topic><topic>Infections</topic><topic>Irritable bowel syndrome</topic><topic>Lipids</topic><topic>Liquid phases</topic><topic>Lyssavirus</topic><topic>Nucleoproteins</topic><topic>Organelles</topic><topic>Phase separation</topic><topic>Physical Sciences</topic><topic>Polymer solubility</topic><topic>Positive feedback</topic><topic>Principles</topic><topic>Proteins</topic><topic>Rabies</topic><topic>Replication</topic><topic>Review</topic><topic>Ribonucleic acid</topic><topic>RNA</topic><topic>RNA polymerase</topic><topic>RNA viruses</topic><topic>Severe acute respiratory syndrome coronavirus 2</topic><topic>Solvents</topic><topic>Structure</topic><topic>Transcription</topic><topic>Viral proteins</topic><topic>Virus research</topic><topic>Viruses</topic><topic>West Nile virus</topic><topic>Zika virus</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Lopez, Nora</creatorcontrib><creatorcontrib>Camporeale, Gabriela</creatorcontrib><creatorcontrib>Salgueiro, Mariano</creatorcontrib><creatorcontrib>Borkosky, Silvia 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Eugenia</au><au>de Prat-Gay, Gonzalo</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Deconstructing virus condensation</atitle><jtitle>PLoS pathogens</jtitle><date>2021-10-14</date><risdate>2021</risdate><volume>17</volume><issue>10</issue><spage>e1009926</spage><epage>e1009926</epage><pages>e1009926-e1009926</pages><issn>1553-7374</issn><issn>1553-7366</issn><eissn>1553-7374</eissn><abstract>Viruses have evolved precise mechanisms for using the cellular physiological pathways for their perpetuation. These virus-driven biochemical events must be separated in space and time from those of the host cell. In recent years, granular structures, known for over a century for rabies virus, were shown to host viral gene function and were named using terms such as viroplasms, replication sites, inclusion bodies, or viral factories (VFs). More recently, these VFs were shown to be liquid-like, sharing properties with membrane-less organelles driven by liquid–liquid phase separation (LLPS) in a process widely referred to as biomolecular condensation. Some of the best described examples of these structures come from negative stranded RNA viruses, where micrometer size VFs are formed toward the end of the infectious cycle. We here discuss some basic principles of LLPS in connection with several examples of VFs and propose a view, which integrates viral replication mechanisms with the biochemistry underlying liquid-like organelles. In this view, viral protein and RNA components gradually accumulate up to a critical point during infection where phase separation is triggered. This yields an increase in transcription that leads in turn to increased translation and a consequent growth of initially formed condensates. According to chemical principles behind phase separation, an increase in the concentration of components increases the size of the condensate. A positive feedback cycle would thus generate in which crucial components, in particular nucleoproteins and viral polymerases, reach their highest levels required for genome replication. Progress in understanding viral biomolecular condensation leads to exploration of novel therapeutics. 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subjects	Biochemistry Biology and Life Sciences Condensates Condensation Critical point Cytoplasm Dengue fever Enzymes Genomes Hepatitis Host-virus relationships Inclusion bodies Infections Irritable bowel syndrome Lipids Liquid phases Lyssavirus Nucleoproteins Organelles Phase separation Physical Sciences Polymer solubility Positive feedback Principles Proteins Rabies Replication Review Ribonucleic acid RNA RNA polymerase RNA viruses Severe acute respiratory syndrome coronavirus 2 Solvents Structure Transcription Viral proteins Virus research Viruses West Nile virus Zika virus
title	Deconstructing virus condensation
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