Whole Genomes from the Extinct Xerces Blue Butterfly Can Help Identify Declining Insect Species

Overview

Journal Elife

Specialty Biology

Date 2024 Oct 4

PMID 39365295

Authors

Toni de-Dios

Claudia Fontsere

Pere Renom

Josefin Stiller

Laia Llovera

Marcela Uliano-Silva

Alejandro Sanchez-Gracia

Charlotte Wright

Esther Lizano

Berta Caballero

Arcadi Navarro

Sergi Civit

Robert K Robbins

Mark Blaxter

Tomas Marques

Roger Vila

Carles Lalueza-Fox

Affiliations

Soon will be listed here.

Abstract

The Xerces Blue () is considered to be the first butterfly to become extinct in historical times. It was notable for its chalky lavender wings with conspicuous white spots on the ventral wings. The last individuals were collected in their restricted habitat, in the dunes near the Presidio military base in San Francisco, in 1941. We sequenced the genomes of four 80- to 100-year-old Xerces Blue, and seven historical and one modern specimens of its closest relative, the Silvery Blue (). We compared these to a novel annotated genome of the Green-Underside Blue (). Phylogenetic relationships inferred from complete mitochondrial genomes indicate that Xerces Blue was a distinct species that diverged from the Silvery Blue lineage at least 850,000 years ago. Using nuclear genomes, both species experienced population growth during the Eemian interglacial period, but the Xerces Blue decreased to a very low effective population size subsequently, a trend opposite to that observed in the Silvery Blue. Runs of homozygosity and deleterious load in the former were significantly greater than in the later, suggesting a higher incidence of inbreeding. These signals of population decline observed in Xerces Blue could be used to identify and monitor other insects threatened by human activities, whose extinction patterns are still not well known.

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Whole genomes from the extinct Xerces Blue butterfly can help identify declining insect species.

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