Unveiling the Evolutionary History of European Vipers and Their Venoms From a Multi‐Omic Approach

Snake genomes attract significant attention from multiple disciplines, including medicine, drug bioprospection, and evolutionary biology. However, genomic research within the Viperidae family has mostly focused on the subfamily Crotalinae, while the true vipers (Viperinae) have largely been overlook...

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Published inMolecular ecology p. e70019
Main Authors Talavera, Adrián, Palmada‐Flores, Marc, Martínez‐Freiría, Fernando, Mochales‐Riaño, Gabriel, Burriel‐Carranza, Bernat, Estarellas, Maria, Fernández‐Guiberteau, Daniel, Camina, Álvaro, Ursenbacher, Sylvain, Vörös, Judit, Halpern, Bálint, Pla, Davinia, Calvete, Juan José, Mikheyev, Alexander S., Marquès‐Bonet, Tomàs, Carranza, Salvador
Format Journal Article
LanguageEnglish
Published England 12.07.2025
Subjects
chromosomal rearrangements
mito‐nuclear discordance
genomics
snakes
Vipera
adaptive introgression
venom evolution
Online AccessGet full text
ISSN0962-1083
1365-294X
1365-294X
DOI10.1111/mec.70019

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Abstract Snake genomes attract significant attention from multiple disciplines, including medicine, drug bioprospection, and evolutionary biology. However, genomic research within the Viperidae family has mostly focused on the subfamily Crotalinae, while the true vipers (Viperinae) have largely been overlooked. European vipers ( Vipera ) have been the subject of extensive research due to their phylogeographic and ecological diversification, as well as their venoms. Nevertheless, phylogeography and systematics in this genus have primarily relied on biased information from mitochondrial genes, which fail to capture the likely effects of introgression and are prone to biases. On the other hand, venom research in this group has been conducted predominantly through proteomics alone. In this study, we generated chromosome‐level genome assemblies for three Vipera species and whole‐genome sequencing data for 94 samples representing 15 Vipera lineages. This comprehensive dataset allowed us to disentangle the phylogenomic relationships of this genus, affected by mito‐nuclear discordance and pervaded by ancestral introgression. Population‐level analyses in the Iberian Peninsula, where the three oldest lineages within Vipera meet, revealed signals of recent adaptive introgression between old‐diverged and ecologically dissimilar species, whereas chromosomal rearrangements isolate species occupying similar niches. Finally, using transcriptomic and proteomic data, we characterised the Vipera toxin‐encoding genes, in which opposing selective forces were unveiled as common drivers of the evolution of venom as an integrated phenotype.
AbstractList Snake genomes attract significant attention from multiple disciplines, including medicine, drug bioprospection, and evolutionary biology. However, genomic research within the Viperidae family has mostly focused on the subfamily Crotalinae, while the true vipers (Viperinae) have largely been overlooked. European vipers ( Vipera ) have been the subject of extensive research due to their phylogeographic and ecological diversification, as well as their venoms. Nevertheless, phylogeography and systematics in this genus have primarily relied on biased information from mitochondrial genes, which fail to capture the likely effects of introgression and are prone to biases. On the other hand, venom research in this group has been conducted predominantly through proteomics alone. In this study, we generated chromosome‐level genome assemblies for three Vipera species and whole‐genome sequencing data for 94 samples representing 15 Vipera lineages. This comprehensive dataset allowed us to disentangle the phylogenomic relationships of this genus, affected by mito‐nuclear discordance and pervaded by ancestral introgression. Population‐level analyses in the Iberian Peninsula, where the three oldest lineages within Vipera meet, revealed signals of recent adaptive introgression between old‐diverged and ecologically dissimilar species, whereas chromosomal rearrangements isolate species occupying similar niches. Finally, using transcriptomic and proteomic data, we characterised the Vipera toxin‐encoding genes, in which opposing selective forces were unveiled as common drivers of the evolution of venom as an integrated phenotype.
Snake genomes attract significant attention from multiple disciplines, including medicine, drug bioprospection, and evolutionary biology. However, genomic research within the Viperidae family has mostly focused on the subfamily Crotalinae, while the true vipers (Viperinae) have largely been overlooked. European vipers (Vipera) have been the subject of extensive research due to their phylogeographic and ecological diversification, as well as their venoms. Nevertheless, phylogeography and systematics in this genus have primarily relied on biased information from mitochondrial genes, which fail to capture the likely effects of introgression and are prone to biases. On the other hand, venom research in this group has been conducted predominantly through proteomics alone. In this study, we generated chromosome-level genome assemblies for three Vipera species and whole-genome sequencing data for 94 samples representing 15 Vipera lineages. This comprehensive dataset allowed us to disentangle the phylogenomic relationships of this genus, affected by mito-nuclear discordance and pervaded by ancestral introgression. Population-level analyses in the Iberian Peninsula, where the three oldest lineages within Vipera meet, revealed signals of recent adaptive introgression between old-diverged and ecologically dissimilar species, whereas chromosomal rearrangements isolate species occupying similar niches. Finally, using transcriptomic and proteomic data, we characterised the Vipera toxin-encoding genes, in which opposing selective forces were unveiled as common drivers of the evolution of venom as an integrated phenotype.Snake genomes attract significant attention from multiple disciplines, including medicine, drug bioprospection, and evolutionary biology. However, genomic research within the Viperidae family has mostly focused on the subfamily Crotalinae, while the true vipers (Viperinae) have largely been overlooked. European vipers (Vipera) have been the subject of extensive research due to their phylogeographic and ecological diversification, as well as their venoms. Nevertheless, phylogeography and systematics in this genus have primarily relied on biased information from mitochondrial genes, which fail to capture the likely effects of introgression and are prone to biases. On the other hand, venom research in this group has been conducted predominantly through proteomics alone. In this study, we generated chromosome-level genome assemblies for three Vipera species and whole-genome sequencing data for 94 samples representing 15 Vipera lineages. This comprehensive dataset allowed us to disentangle the phylogenomic relationships of this genus, affected by mito-nuclear discordance and pervaded by ancestral introgression. Population-level analyses in the Iberian Peninsula, where the three oldest lineages within Vipera meet, revealed signals of recent adaptive introgression between old-diverged and ecologically dissimilar species, whereas chromosomal rearrangements isolate species occupying similar niches. Finally, using transcriptomic and proteomic data, we characterised the Vipera toxin-encoding genes, in which opposing selective forces were unveiled as common drivers of the evolution of venom as an integrated phenotype.
Author Mikheyev, Alexander S.
Pla, Davinia
Burriel‐Carranza, Bernat
Marquès‐Bonet, Tomàs
Ursenbacher, Sylvain
Vörös, Judit
Talavera, Adrián
Mochales‐Riaño, Gabriel
Camina, Álvaro
Palmada‐Flores, Marc
Martínez‐Freiría, Fernando
Calvete, Juan José
Estarellas, Maria
Carranza, Salvador
Fernández‐Guiberteau, Daniel
Halpern, Bálint
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Keywords chromosomal rearrangements
mito‐nuclear discordance
genomics
snakes
Vipera
adaptive introgression
venom evolution
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