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Main Authors: Thomy, Julie, Henri, Julien, Demory, David, Sanchez, Frederic, Escande, Marie-Line, Mirambeau, Gilles, Grimsley, Nigel, Yau, Sheree
Format: Artículo científico
Language:en
Published: Virus evolution 2026
Online Access:https://pubmed.ncbi.nlm.nih.gov/41700146/
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author Thomy, Julie
Henri, Julien
Demory, David
Sanchez, Frederic
Escande, Marie-Line
Mirambeau, Gilles
Grimsley, Nigel
Yau, Sheree
author_facet Thomy, Julie
Henri, Julien
Demory, David
Sanchez, Frederic
Escande, Marie-Line
Mirambeau, Gilles
Grimsley, Nigel
Yau, Sheree
Thomy, Julie
Henri, Julien
Demory, David
Sanchez, Frederic
Escande, Marie-Line
Mirambeau, Gilles
Grimsley, Nigel
Yau, Sheree
collection PubMed - marine biology
contents Genomic analysis of -infecting viruses reveals a hypervariable region associated with host-virus interactions. Thomy, Julie Henri, Julien Demory, David Sanchez, Frederic Escande, Marie-Line Mirambeau, Gilles Grimsley, Nigel Yau, Sheree While the genus , known to infect prasinophyte green algae (class Mamiellophyceae), is abundant in the oceans, the genetic mechanisms governing the ecology and (co)evolution of these viruses remain poorly understood. In this study, we sequenced the complete genomes of eighteen viruses infecting the cosmopolitan unicellular green alga (OtVs) and one specific to (McV-20 T). Of these viruses, 12 were previously isolated from the coastal Mediterranean Sea and seven were newly isolated from two different geographical locations (i.e. the South Pacific Ocean and the North Sea). Phylogenetic analysis classified these viruses as new members of the genus and defined three distinct OtV clades: designated OtV-type 1, OtV-type 2a, and OtV-type 2b. The OtV-type 1 includes three new viruses isolated from the Pacific Ocean and the previously sequenced genome OtV6. The OtV-type 1 form a large cluster within the -infecting virus clade, sharing five unique homologous genes with all viruses. In addition, genetic features of OtV-type 1, including a higher number of CDSs (~260) and lower Guanine-Cytosine content (GC) content (~41%), were more closely allied to viruses than to those of OtVs, suggesting an alternative host or a recent host switch from to By analysing the OtV genomes, we found a faster-evolving central hypervariable region (HVR), where the OtV-type 2b displayed the largest region, i.e. three times longer than other OtVs. This region encodes genes mainly associated with host cell recognition and attachment and under strong selective pressure (positive and negative). Notably, most viruses associated with OtV-type 2b showed the broadest host range. Infection dynamics between the hosts and the viruses appeared highly specific to host-virus pairs, suggesting complex interactions in the -prasinovirus system. Finally, by observing viral lysates with electron microscopy, we observed novel morphologies never described for these viruses. Overall, this study provides new insights into the genetic diversity of prasinoviruses and describes for the first time a viral plasticity that might be strongly shaped by antagonistic coevolution with their hosts.
format Artículo científico
id pubmed_41700146
institution PubMed
language en
publishDate 2026
publisher Virus evolution
record_format pubmed
spellingShingle Genomic analysis of -infecting viruses reveals a hypervariable region associated with host-virus interactions.
Thomy, Julie
Henri, Julien
Demory, David
Sanchez, Frederic
Escande, Marie-Line
Mirambeau, Gilles
Grimsley, Nigel
Yau, Sheree
Genomic analysis of -infecting viruses reveals a hypervariable region associated with host-virus interactions. Thomy, Julie Henri, Julien Demory, David Sanchez, Frederic Escande, Marie-Line Mirambeau, Gilles Grimsley, Nigel Yau, Sheree While the genus , known to infect prasinophyte green algae (class Mamiellophyceae), is abundant in the oceans, the genetic mechanisms governing the ecology and (co)evolution of these viruses remain poorly understood. In this study, we sequenced the complete genomes of eighteen viruses infecting the cosmopolitan unicellular green alga (OtVs) and one specific to (McV-20 T). Of these viruses, 12 were previously isolated from the coastal Mediterranean Sea and seven were newly isolated from two different geographical locations (i.e. the South Pacific Ocean and the North Sea). Phylogenetic analysis classified these viruses as new members of the genus and defined three distinct OtV clades: designated OtV-type 1, OtV-type 2a, and OtV-type 2b. The OtV-type 1 includes three new viruses isolated from the Pacific Ocean and the previously sequenced genome OtV6. The OtV-type 1 form a large cluster within the -infecting virus clade, sharing five unique homologous genes with all viruses. In addition, genetic features of OtV-type 1, including a higher number of CDSs (~260) and lower Guanine-Cytosine content (GC) content (~41%), were more closely allied to viruses than to those of OtVs, suggesting an alternative host or a recent host switch from to By analysing the OtV genomes, we found a faster-evolving central hypervariable region (HVR), where the OtV-type 2b displayed the largest region, i.e. three times longer than other OtVs. This region encodes genes mainly associated with host cell recognition and attachment and under strong selective pressure (positive and negative). Notably, most viruses associated with OtV-type 2b showed the broadest host range. Infection dynamics between the hosts and the viruses appeared highly specific to host-virus pairs, suggesting complex interactions in the -prasinovirus system. Finally, by observing viral lysates with electron microscopy, we observed novel morphologies never described for these viruses. Overall, this study provides new insights into the genetic diversity of prasinoviruses and describes for the first time a viral plasticity that might be strongly shaped by antagonistic coevolution with their hosts.
title Genomic analysis of -infecting viruses reveals a hypervariable region associated with host-virus interactions.
url https://pubmed.ncbi.nlm.nih.gov/41700146/