Parallel Evolution in an Island Archipelago Revealed by Genomic Sequencing of Hipposideros Leaf-nosed Bats

Overview

Journal Evolution

Publisher Oxford University Press

Specialty Biology

Date 2024 Mar 8

PMID 38457362

Authors

Tyrone H Lavery

Devon A DeRaad

Piokera S Holland

Karen V Olson

Lucas H DeCicco

Jennifer M Seddon

Luke K-P Leung

Robert G Moyle

Affiliations

Soon will be listed here.

Abstract

Body size is a key morphological attribute, often used to delimit species boundaries among closely related taxa. But body size can evolve in parallel, reaching similar final states despite independent evolutionary and geographic origins, leading to faulty assumptions of evolutionary history. Here, we document parallel evolution in body size in the widely distributed leaf-nosed bat genus Hipposideros, which has misled both taxonomic and evolutionary inference. We sequenced reduced representation genomic loci and measured external morphological characters from three closely related species from the Solomon Islands archipelago, delimited by body size. Species tree reconstruction confirms the paraphyly of two morphologically designated species. The nonsister relationship between large-bodied H. dinops lineages found on different islands indicates that large-bodied ecomorphs have evolved independently at least twice in the history of this radiation. A lack of evidence for gene flow between sympatric, closely related taxa suggests the rapid evolution of strong reproductive isolating barriers between morphologically distinct populations. Our results position Solomon Islands Hipposideros as a novel vertebrate system for studying the repeatability of parallel evolution under natural conditions. We conclude by offering testable hypotheses for how geography and ecology could be mediating the repeated evolution of large-bodied Hipposideros lineages in the Solomon Islands.

Citing Articles

Genomic patterns in the dwarf kingfishers of northern Melanesia reveal a mechanistic framework explaining the paradox of the great speciators.

DeRaad D, Files A, DeCicco L, Martin R, McCullough J, Holland P Evol Lett. 2024; 8(6):813-827.

PMID: 39677579 PMC: 11637610. DOI: 10.1093/evlett/qrae035.

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