1. Exploring The Role Of Genome And Structural Ions In Preventing Viral Capsid Collapse During Dehydration
- Author
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Natalia Martín-González, Diego M. A. Guérin, Aritz Durana, Pedro J. de Pablo, Gerardo Anibal Marti, and Sofía M Guérin Darvas
- Subjects
Paper ,Models, Molecular ,0301 basic medicine ,triatoma virus ,viruses ,water ,Molecular Conformation ,Genome, Viral ,Special Issue on Viral Capsids ,virus dehydration ,Genome ,Virus ,Ciencias Biológicas ,03 medical and health sciences ,Tobacco necrosis virus ,Capsid ,medicine ,General Materials Science ,Dehydration ,icosahedral non-enveloped viruses ,hydrophobic gate ,Cricket paralysis virus ,Dicistroviridae ,particles ,atomic force microscopy ,biology ,Chemistry ,Water ,crystal-structure ,resolution ,Condensed Matter Physics ,biology.organism_classification ,medicine.disease ,Biofísica ,030104 developmental biology ,cricket paralysis virus ,Solvents ,Biophysics ,tobacco necrosis virus ,Triatoma virus ,AFM ,Desiccation ,CIENCIAS NATURALES Y EXACTAS ,mechanics ,hydrophobic nanopores - Abstract
Even though viruses evolve mainly in liquid milieu, their horizontal transmission routes often include episodes of dry environment. Along their life cycle, some insect viruses, such as viruses from the Dicistroviridae family, withstand dehydrated conditions with presently unknown consequences to their structural stability. Here, we use atomic force microscopy to monitor the structural changes of viral particles of Triatoma virus (TrV) after desiccation. Our results demonstrate that TrV capsids preserve their genome inside, conserving their height after exposure to dehydrating conditions, which is in stark contrast with other viruses that expel their genome when desiccated. Moreover, empty capsids (without genome) resulted in collapsed particles after desiccation. We also explored the role of structural ions in the dehydration process of the virions (capsid containing genome) by chelating the accessible cations from the external solvent milieu. We observed that ion suppression helps to keep the virus height upon desiccation. Our results show that under drying conditions, the genome of TrV prevents the capsid from collapsing during dehydration, while the structural ions are responsible for promoting solvent exchange through the virion wall. TEM images were collected at the Servicio General de Microscopia Analitica y de Alta Resolucion en Biomedicina (SGIKER, UPV/EHU). PJP thanks FIS2014-59562-R, FIS2015-71108-REDT, Fundacion BBVA and 'Maria de Maeztu' Program for Units of Excellence in R&D (MDM-2014-0377), and FIS2017-89549-R. DMAG thanks the Servicio de Microscopia Analitica y de Alta Resolucion en Biomedicina of SGIker (UPV/EHU) for TEM measurements. GAM is a staff member of CONICET. This work was partially supported by a grant to DMAG from the Ministerio de Ciencia e Innovacion (BFU2012-36241), and Gobierno Vasco (Elkartek KK-2017/00008), Spain. SMGD thanks the Fundacion Biofisica Bizkaia, Spain, for traveling support to visit PJP's lab. GAM and DMAG acknowledge a grant from the CYTED (216RT0506). GAM is recipient of grants from the Agencia Nacional de Promocion Cientifica y Tecnica (PICT No 2014-1536 and 2015-0665), Argentina.
- Published
- 2018